Structural basis of Ca2+-dependent activation and lipid transport by a TMEM16 scramblase

The lipid distribution of plasma membranes of eukaryotic cells is asymmetric and phospholipid scramblases disrupt this asymmetry by mediating the rapid, nonselective transport of lipids down their concentration gradients. As a result, phosphatidylserine is exposed to the outer leaflet of membrane, an important step in extracellular signaling networks controlling processes such as apoptosis, blood coagulation, membrane fusion and repair. Several TMEM16 family members have been identified as Ca2+-activated scramblases, but the mechanisms underlying their Ca2+-dependent gating and their effects on the surrounding lipid bilayer remain poorly understood. Here, we describe three high-resolution cryo-electron microscopy structures of a fungal scramblase from Aspergillus fumigatus, afTMEM16, reconstituted in lipid nanodiscs. These structures reveal that Ca2+-dependent activation of the scramblase entails global rearrangement of the transmembrane and cytosolic domains. These structures, together with functional experiments, suggest that activation of the protein thins the membrane near the transport pathway to facilitate rapid transbilayer lipid movement.

[1]  E. Lindahl,et al.  Accelerated cryo-EM structure determination with parallelisation using GPUs in RELION-2 , 2016, bioRxiv.

[2]  B. Valeur,et al.  Mathematical functions for the analysis of luminescence decays with underlying distributions 1. Kohlrausch decay function (stretched exponential) , 2005 .

[3]  Mattia Malvezzi,et al.  Known structures and unknown mechanisms of TMEM16 scramblases and channels , 2018, The Journal of general physiology.

[4]  J. Szostak,et al.  Flip-flop-induced relaxation of bending energy: implications for membrane remodeling. , 2009, Biophysical Journal.

[5]  Cristina Paulino,et al.  Structural basis for anion conduction in the calcium-activated chloride channel TMEM16A , 2017, eLife.

[6]  H. Ingólfsson,et al.  Effects of green tea catechins on gramicidin channel function and inferred changes in bilayer properties , 2011, FEBS letters.

[7]  F. Goñi,et al.  The Physical Properties of Ceramides in Membranes. , 2018, Annual review of biophysics.

[8]  George Khelashvili,et al.  Gating mechanism of the extracellular entry to the lipid pathway in a TMEM16 scramblase , 2018, Nature Communications.

[9]  Helgi I. Ingólfsson,et al.  Lipid bilayer regulation of membrane protein function: gramicidin channels as molecular force probes , 2010, Journal of The Royal Society Interface.

[10]  Nathaniel Echols,et al.  EMRinger: Side-chain-directed model and map validation for 3D Electron Cryomicroscopy , 2015, Nature Methods.

[11]  K. Segawa,et al.  Exposure of phosphatidylserine on the cell surface , 2016, Cell Death and Differentiation.

[12]  Helgi I. Ingólfsson,et al.  Screening for small molecules' bilayer-modifying potential using a gramicidin-based fluorescence assay. , 2010, Assay and drug development technologies.

[13]  D. Tieleman,et al.  Thermodynamics of flip-flop and desorption for a systematic series of phosphatidylcholine lipids , 2009 .

[14]  O. Andersen,et al.  Single-molecule methods for monitoring changes in bilayer elastic properties. , 2007, Methods in molecular biology.

[15]  D. Engelman,et al.  Lipid bilayer thickness varies linearly with acyl chain length in fluid phosphatidylcholine vesicles. , 1983, Journal of molecular biology.

[16]  F. Goñi,et al.  Complex Effects of 24:1 Sphingolipids in Membranes Containing Dioleoylphosphatidylcholine and Cholesterol. , 2017, Langmuir : the ACS journal of surfaces and colloids.

[17]  A. Menon,et al.  Out-of-the-groove transport of lipids by TMEM16 and GPCR scramblases , 2018, Proceedings of the National Academy of Sciences.

[18]  Heymann Jb,et al.  Bsoft: Image and Molecular Processing in Electron Microscopy , 2001 .

[19]  Yusuf A. Hannun,et al.  Principles of bioactive lipid signalling: lessons from sphingolipids , 2008, Nature Reviews Molecular Cell Biology.

[20]  H. C. Hartzell,et al.  Lipids and ions traverse the membrane by the same physical pathway in the nhTMEM16 scramblase , 2017, eLife.

[21]  Cristina Paulino,et al.  Activation mechanism of the calcium-activated chloride channel TMEM16A revealed by cryo-EM , 2017, Nature.

[22]  S. Sligar,et al.  Chapter 11 - Reconstitution of membrane proteins in phospholipid bilayer nanodiscs. , 2009, Methods in enzymology.

[23]  Michael Grabe,et al.  Atomistic insight into lipid translocation by a TMEM16 scramblase , 2016, Proceedings of the National Academy of Sciences.

[24]  R. Dutzler,et al.  Independent activation of ion conduction pores in the double-barreled calcium-activated chloride channel TMEM16A , 2016, The Journal of general physiology.

[25]  J. Griffin,et al.  Minor plasma lipids modulate clotting factor activities and may affect thrombosis risk , 2017, Research and practice in thrombosis and haemostasis.

[26]  Vincent B. Chen,et al.  Correspondence e-mail: , 2000 .

[27]  Daniel L. Minor,et al.  Cryo-EM structures of the TMEM16A calcium-activated chloride channel , 2017, Nature.

[28]  Thomas D. Newport,et al.  The structural basis of lipid scrambling and inactivation in the endoplasmic reticulum scramblase TMEM16K , 2018, Nature Communications.

[29]  M Radermacher,et al.  DoG Picker and TiltPicker: software tools to facilitate particle selection in single particle electron microscopy. , 2009, Journal of structural biology.

[30]  C. Nimigean,et al.  Ligand discrimination and gating in cyclic nucleotide-gated ion channels from apo and partial agonist-bound cryo-EM structures , 2018, eLife.

[31]  Sonia Borodzicz,et al.  Sphingolipids in cardiovascular diseases and metabolic disorders , 2015, Lipids in Health and Disease.

[32]  Anant K. Menon,et al.  Ca2+-dependent phospholipid scrambling by a reconstituted TMEM16 ion channel , 2013, Nature Communications.

[33]  D. Tieleman,et al.  Thermodynamic analysis of the effect of cholesterol on dipalmitoylphosphatidylcholine lipid membranes. , 2009, Journal of the American Chemical Society.

[34]  Liana C. Silva,et al.  Membrane domain formation, interdigitation, and morphological alterations induced by the very long chain asymmetric C24:1 ceramide. , 2008, Biophysical journal.

[35]  Christopher Irving,et al.  Appion: an integrated, database-driven pipeline to facilitate EM image processing. , 2009, Journal of structural biology.

[36]  H. Terashima,et al.  Purified TMEM16A is sufficient to form Ca2+-activated Cl− channels , 2013, Proceedings of the National Academy of Sciences.

[37]  O. Andersen,et al.  Kinetics of gramicidin channel formation in lipid bilayers: transmembrane monomer association. , 1990, Science.

[38]  G. Heijne,et al.  GFP-based optimization scheme for the overexpression and purification of eukaryotic membrane proteins in Saccharomyces cerevisiae , 2008, Nature Protocols.

[39]  Y. Jan,et al.  A comprehensive search for calcium binding sites critical for TMEM16A calcium-activated chloride channel activity , 2014, eLife.

[40]  Nick V Grishin,et al.  PROMALS3D: multiple protein sequence alignment enhanced with evolutionary and three-dimensional structural information. , 2014, Methods in molecular biology.

[41]  Anant K. Menon,et al.  The nhTMEM16 Scramblase Is Also a Nonselective Ion Channel. , 2016, Biophysical journal.

[42]  R. Dutzler,et al.  X-ray structure of a calcium-activated TMEM 16 lipid scramblase , 2014 .

[43]  H. C. Hartzell,et al.  Explaining Calcium-Dependent Gating of Anoctamin-1 Chloride Channels Requires a Revised Topology , 2012, Circulation research.

[44]  Anchi Cheng,et al.  Automated molecular microscopy: the new Leginon system. , 2005, Journal of structural biology.

[45]  D. Agard,et al.  MotionCor2: anisotropic correction of beam-induced motion for improved cryo-electron microscopy , 2017, Nature Methods.

[46]  Conrad C. Huang,et al.  UCSF Chimera—A visualization system for exploratory research and analysis , 2004, J. Comput. Chem..

[47]  David J. Fleet,et al.  cryoSPARC: algorithms for rapid unsupervised cryo-EM structure determination , 2017, Nature Methods.

[48]  Jarred M. Whitlock,et al.  Identification of a lipid scrambling domain in ANO6/TMEM16F , 2015, eLife.

[49]  A. Steven,et al.  One number does not fit all: mapping local variations in resolution in cryo-EM reconstructions. , 2013, Journal of structural biology.

[50]  J. Griffin,et al.  Sphingolipids as Bioactive Regulators of Thrombin Generation* , 2004, Journal of Biological Chemistry.

[51]  B. Wallace,et al.  HOLE: a program for the analysis of the pore dimensions of ion channel structural models. , 1996, Journal of molecular graphics.

[52]  Y. Jan,et al.  The Sixth Transmembrane Segment Is a Major Gating Component of the TMEM16A Calcium-Activated Chloride Channel , 2018, Neuron.

[53]  P. Williamson,et al.  Getting to the Outer Leaflet: Physiology of Phosphatidylserine Exposure at the Plasma Membrane. , 2016, Physiological reviews.

[54]  N. Grigorieff,et al.  CTFFIND4: Fast and accurate defocus estimation from electron micrographs , 2015, bioRxiv.

[55]  R. Ravazzolo,et al.  Ion channel and lipid scramblase activity associated with expression of TMEM16F/ANO6 isoforms , 2015, The Journal of physiology.

[56]  A. Di Lorenzo,et al.  S1P Signaling and De Novo Biosynthesis in Blood Pressure Homeostasis , 2016, The Journal of Pharmacology and Experimental Therapeutics.

[57]  P. Emsley,et al.  Features and development of Coot , 2010, Acta crystallographica. Section D, Biological crystallography.

[58]  A. Menon,et al.  Lipid flippases and their biological functions , 2006, Cellular and Molecular Life Sciences CMLS.

[59]  Juha T Huiskonen,et al.  The structural basis of lipid scrambling and inactivation in the endoplasmic reticulum scramblase TMEM16K , 2019, Nature Communications.

[60]  Randy J. Read,et al.  Acta Crystallographica Section D Biological , 2003 .

[61]  R. Dutzler,et al.  X-ray structure of a calcium-activated TMEM16 lipid scramblase , 2014, Nature.