Substrate Selectivity of a P4‐ATPase Flippase

Abstract

Phospholipids, the primary structural components of cell membranes, are distributed unequally across the membrane. The sphingolipids, including sphingomyelin (SM) and glycosphingolipids, are enriched on the exofacial surface of the plasma membrane or the luminal surfaces of internal organelles, while the cytofacial leaflet is enriched in the aminophospholipids, phophatidylserine (PS) and phosphatidylethanolamine (PE). Contributing to maintenance of this asymmetry is a combination of slow passive transbilayer phospholipid movement, trapping by cytofacial proteins and the activity of a number of energy‐dependent transporters. The substrate specificity and directionality of these pumps defines the transbilayer asymmetry of phospholipids. Two transporter superfamilies, ABC transporters and P‐type ATPases, account for these activities and move lipids in either the exofacial (floppase) or cytofacial (flippase) directions, respectively. In previous studies we have characterized the biochemical requirements and substrate specificity for a PS specific flippase activity in human red blood cells. Transport is ATP‐dependent and sensitive to vanadate and sulfhydryl‐modification. This flippase is selective for the sn‐1,2‐isomer of PS. Transport is diminished by modification of the PS headgroup amine (with the exception of mono‐methylation), carboxyl and phosphate groups, while a variety of fatty acyl groups and the D‐serine analog are accommodated. Red blood cells express two members of the P4‐type ATPase subfamily, ATP8A1 and ATP11C, that are likely responsible for this activity. Here, we report on the heterologous expression, purification, and functional assaying of hexahistidine‐tagged constructs of Atp8a1 with and without its cognate accessory subunit, Cdc50a. Purified Atp8a1 is vanadate‐sensitive and dependent upon Cdc50a co‐expression and PS for robust ATPase activity, although lipid specificity is not dependent on the presence of Cdc50a. In addition to reconstituting the flippase activity of Atp8a1 and ATP11c in vitro, our efforts are focused on rational mutagenesis of Atp8a1 to identify the lipid transport path and the determinants of substrate specificity, directed by homology modeling and the lipid‐binding characteristics of the closest members of the P‐type superfamily. X‐ray crystal structures of the SERCA pump in conformation E2 (PDB 2AGV) display a PE glycerol backbone and head group tightly pinched by helices M2 and M4 with PE's acyl chains extending between helices M2 and M6. This PE‐binding site implies a mechanism for how the P4lipid‐binding site and transport pathway evolved from ancestor P‐types designed to move simple cations. With these clues, we aim to identify the PS binding site and deduce the origin of the sn‐1,2‐stereospecificity of Atp8a1.This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.