Phospholipid scrambling induced by an ion channel/metabolite transporter complex
Han Ben Niu, Masahiro Maruoka, Yuki Noguchi, Hidetaka Kosako, Jun Suzuki
Abstract
Cells establish the asymmetrical distribution of phospholipids and alter their distribution by phospholipid scrambling (PLS) to adapt to environmental changes. Here, we demonstrate that a protein complex, consisting of the ion channel Tmem63b and the thiamine transporter Slc19a2, induces PLS upon calcium (Ca2+) stimulation. Through revival screening using a CRISPR sgRNA library on high PLS cells, we identify Tmem63b as a PLS-inducing factor. Ca2+ stimulation-mediated PLS is suppressed by deletion of Tmem63b, while human disease-related Tmem63b mutants induce constitutive PLS. To search for a molecular link between Ca2+ stimulation and PLS, we perform revival screening on Tmem63b-overexpressing cells, and identify Slc19a2 and the Ca2+-activated K+ channel Kcnn4 as PLS-regulating factors. Deletion of either of these genes decreases PLS activity. Biochemical screening indicates that Tmem63b and Slc19a2 form a heterodimer. These results demonstrate that a Tmem63b/Slc19a2 heterodimer induces PLS upon Ca2+ stimulation, along with Kcnn4 activation. Phospholipid scrambling is used by cells to alter lipid asymmetry on the plasma membrane. Here, the authors performed CRISPR screenings to identify a heterodimer formed by Tmem63b and Slc19a2 that induces calcium-dependent phospholipid scrambling.