Structural basis for the alternating access mechanism of the cation diffusion facilitator YiiP

Significance Zn2+ is a micronutrient that plays important roles throughout the body. We are interested in molecular mechanisms by which appropriate levels of Zn2+ are maintained in cells. We have combined structural and functional studies to deduce the physical changes that a bacterial transporter uses to carry Zn2+ across cell membranes. We have identified parts of the molecule that remain static and characterized the movements of other parts that bind Zn2+ ions and allow them to cross the membrane. YiiP is a dimeric antiporter from the cation diffusion facilitator family that uses the proton motive force to transport Zn2+ across bacterial membranes. Previous work defined the atomic structure of an outward-facing conformation, the location of several Zn2+ binding sites, and hydrophobic residues that appear to control access to the transport sites from the cytoplasm. A low-resolution cryo-EM structure revealed changes within the membrane domain that were associated with the alternating access mechanism for transport. In the current work, the resolution of this cryo-EM structure has been extended to 4.1 Å. Comparison with the X-ray structure defines the differences between inward-facing and outward-facing conformations at an atomic level. These differences include rocking and twisting of a four-helix bundle that harbors the Zn2+ transport site and controls its accessibility within each monomer. As previously noted, membrane domains are closely associated in the dimeric structure from cryo-EM but dramatically splayed apart in the X-ray structure. Cysteine crosslinking was used to constrain these membrane domains and to show that this large-scale splaying was not necessary for transport activity. Furthermore, dimer stability was not compromised by mutagenesis of elements in the cytoplasmic domain, suggesting that the extensive interface between membrane domains is a strong determinant of dimerization. As with other secondary transporters, this interface could provide a stable scaffold for movements of the four-helix bundle that confers alternating access of these ions to opposite sides of the membrane.

[1]  T. Kambe Molecular architecture and function of ZnT transporters. , 2012, Current topics in membranes.

[2]  S. Silver,et al.  Ion efflux systems involved in bacterial metal resistances , 1995, Journal of Industrial Microbiology.

[3]  E. Egelman A robust algorithm for the reconstruction of helical filaments using single-particle methods. , 2000, Ultramicroscopy.

[4]  Yigong Shi Common folds and transport mechanisms of secondary active transporters. , 2013, Annual review of biophysics.

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

[6]  D. Fu,et al.  Kinetic Study of the Antiport Mechanism of an Escherichia coli Zinc Transporter, ZitB* , 2004, Journal of Biological Chemistry.

[7]  D. Fu,et al.  Lipid-tuned Zinc Transport Activity of Human ZnT8 Protein Correlates with Risk for Type-2 Diabetes*♦ , 2016, The Journal of Biological Chemistry.

[8]  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.

[9]  Leonardo G. Trabuco,et al.  Flexible fitting of atomic structures into electron microscopy maps using molecular dynamics. , 2008, Structure.

[10]  C. Jaroniec,et al.  Insights into the mode of action of a putative zinc transporter CzrB in Thermus thermophilus. , 2008, Structure.

[11]  L. Forrest,et al.  The structural basis of secondary active transport mechanisms. , 2011, Biochimica et biophysica acta.

[12]  D. Eide,et al.  Biochemical Properties of Vacuolar Zinc Transport Systems ofSaccharomyces cerevisiae * , 2002, The Journal of Biological Chemistry.

[13]  Daniel Raimunda,et al.  Functional characterization of the CDF transporter SMc02724 (SmYiiP) in Sinorhizobium meliloti: Roles in manganese homeostasis and nodulation. , 2014, Biochimica et biophysica acta.

[14]  C. Rensing,et al.  Functional analysis of the Escherichia coli zinc transporter ZitB. , 2002, FEMS microbiology letters.

[15]  Hemant D. Tagare,et al.  The Local Resolution of Cryo-EM Density Maps , 2013, Nature Methods.

[16]  S. Thomine,et al.  Arabidopsis thaliana MTP1 is a Zn transporter in the vacuolar membrane which mediates Zn detoxification and drives leaf Zn accumulation , 2005, FEBS letters.

[17]  O. Jardetzky,et al.  Simple Allosteric Model for Membrane Pumps , 1966, Nature.

[18]  M. Nagao,et al.  Overview of mammalian zinc transporters , 2003, Cellular and Molecular Life Sciences CMLS.

[19]  I. Paulsen,et al.  A Novel Family of Ubiquitous Heavy Metal Ion Transport Proteins , 1997, The Journal of Membrane Biology.

[20]  Yinan Wei,et al.  Binding and Transport of Metal Ions at the Dimer Interface of the Escherichia coli Metal Transporter YiiP* , 2006, Journal of Biological Chemistry.

[21]  D. Eide Zinc transporters and the cellular trafficking of zinc. , 2006, Biochimica et biophysica acta.

[22]  N. Coudray,et al.  Deducing the symmetry of helical assemblies: Applications to membrane proteins. , 2016, Journal of structural biology.

[23]  D. Fu,et al.  Structural Basis for Auto-regulation of the Zinc Transporter YiiP , 2009, Nature Structural &Molecular Biology.

[24]  P. Penczek,et al.  Inward-facing conformation of the zinc transporter YiiP revealed by cryoelectron microscopy , 2012, Proceedings of the National Academy of Sciences.

[25]  D. Blaudez,et al.  Phylogenetic and functional analysis of the Cation Diffusion Facilitator (CDF) family: improved signature and prediction of substrate specificity , 2007, BMC Genomics.

[26]  D. Fu,et al.  Oligomeric State of the Escherichia coli Metal Transporter YiiP* , 2004, Journal of Biological Chemistry.

[27]  D. Fu,et al.  Structure of the Zinc Transporter YiiP , 2007, Science.

[28]  O. Boudker,et al.  Structural perspectives on secondary active transporters. , 2010, Trends in pharmacological sciences.

[29]  D. Fu,et al.  Selective Metal Binding to a Membrane-embedded Aspartate in the Escherichia coli Metal Transporter YiiP (FieF)* , 2005, Journal of Biological Chemistry.

[30]  Bosco K. Ho,et al.  HOLLOW: Generating Accurate Representations of Channel and Interior Surfaces in Molecular Structures , 2008, BMC Structural Biology.

[31]  D. Fu,et al.  Visualizing the kinetic power stroke that drives proton-coupled Zn(II) transport , 2014, Nature.

[32]  K Nadassy,et al.  Analysis of zinc binding sites in protein crystal structures , 1998, Protein science : a publication of the Protein Society.

[33]  C. Rensing,et al.  Characteristics of Zinc Transport by Two Bacterial Cation Diffusion Facilitators from Ralstonia metallidurans CH34 and Escherichia coli , 2004, Journal of bacteriology.

[34]  D. Fu,et al.  Thermodynamic Studies of the Mechanism of Metal Binding to the Escherichia coli Zinc Transporter YiiP* , 2004, Journal of Biological Chemistry.

[35]  N. Yan Structural advances for the major facilitator superfamily (MFS) transporters. , 2013, Trends in biochemical sciences.

[36]  Janne Jänis,et al.  Zinc coordination spheres in protein structures. , 2013, Inorganic chemistry.