Interaction of GAT1 with sodium ions: from efficient recruitment to stabilisation of substrate and conformation

The human GABA transporter (GAT1) is a membrane transporter that mediates the reuptake of the neurotransmitter GABA from the synaptic cleft into neurons and glial cells. Dysregulation of the transport cycle has been associated with epilepsy and neuropsychiatric disorders, highlighting the crucial role of the transporter in maintaining homeostasis of brain GABA levels. GAT1 is a secondary active transporter that couples the movement of substrate to the simultaneous transport of sodium and chloride ions along their electrochemical gradients. Using MD simulations, we identified a novel sodium recruiting site at the entrance to the outer vestibule, which attracts positively charged ions and increases the local sodium concentration, thereby indirectly increasing sodium affinity. Mutations of negatively charged residues at the recruiting site slowed the binding kinetics, while experimental data revealed a change in sodium dependency of GABA uptake and a reduction of sodium affinity. Simulation showed that sodium displays a higher affinity for the sodium binding site NA2, which plays a role in stabilisation of the outward-open conformation. We directly show that the presence of a sodium ion bound to NA2 increases the stability of the closed inner gate and restrains motions of TM5. We find that sodium is only weakly bound to NA1 in the absence of GABA, while the presence of the substrate strengthens the interaction due to the completed ion coordinating shell, explaining cooperativity between GABA and sodium.

[1]  T. Stockner,et al.  Ligand coupling mechanism of the human serotonin transporter differentiates substrates from inhibitors , 2024, Nature communications.

[2]  Chuangye Yan,et al.  Molecular basis for substrate recognition and transport of human GABA transporter GAT1 , 2023, Nature Structural & Molecular Biology.

[3]  K. Wanner,et al.  Cryo-EM structure of GABA transporter 1 reveals substrate recognition and transport mechanism , 2023, Nature Structural & Molecular Biology.

[4]  T. Stockner,et al.  A comparative review on the well-studied GAT1 and the understudied BGT-1 in the brain , 2023, Frontiers in Physiology.

[5]  T. Hummel,et al.  Drosophila melanogaster as a model for unraveling unique molecular features of epilepsy elicited by human GABA transporter 1 variants , 2023, Frontiers in Neuroscience.

[6]  V. Katritch,et al.  Structural basis of GABA reuptake inhibition , 2022, Nature.

[7]  T. Hummel,et al.  Molecular and Clinical Repercussions of GABA Transporter 1 Variants Gone Amiss: Links to Epilepsy and Developmental Spectrum Disorders , 2022, Frontiers in Molecular Biosciences.

[8]  H. Sitte,et al.  Occlusion of the human serotonin transporter is mediated by serotonin-induced conformational changes in the bundle domain , 2022, The Journal of biological chemistry.

[9]  T. Stockner,et al.  Sodium Binding Stabilizes the Outward-Open State of SERT by Limiting Bundle Domain Motions , 2022, Cells.

[10]  E. Gouaux,et al.  Illumination of serotonin transporter mechanism and role of the allosteric site , 2021, Science advances.

[11]  D. Hassabis,et al.  AlphaFold Protein Structure Database: massively expanding the structural coverage of protein-sequence space with high-accuracy models , 2021, Nucleic Acids Res..

[12]  A. Ghit,et al.  GABAA receptors: structure, function, pharmacology, and related disorders , 2021, Journal of Genetic Engineering and Biotechnology.

[13]  Oriol Vinyals,et al.  Highly accurate protein structure prediction with AlphaFold , 2021, Nature.

[14]  T. Stockner,et al.  Investigating the Mechanism of Sodium Binding to SERT Using Direct Simulations , 2021, Frontiers in Cellular Neuroscience.

[15]  M. Freissmuth,et al.  Functional and Biochemical Consequences of Disease Variants in Neurotransmitter Transporters: A Special Emphasis on Folding and Trafficking Deficits , 2020, Pharmacology & therapeutics.

[16]  G. Szakács,et al.  Human ABCB1 with an ABCB11-like degenerate nucleotide binding site maintains transport activity by avoiding nucleotide occlusion , 2020, PLoS genetics.

[17]  E. Gouaux,et al.  Serotonin transporter–ibogaine complexes illuminate mechanisms of inhibition and transport , 2019, Nature.

[18]  Michel A Cuendet,et al.  Substrate-modulated unwinding of transmembrane helices in the NSS transporter LeuT , 2018, Science Advances.

[19]  Antoniya A. Aleksandrova,et al.  Structural elements required for coupling ion and substrate transport in the neurotransmitter transporter homolog LeuT , 2018, Proceedings of the National Academy of Sciences.

[20]  Thomas Stockner,et al.  The Environment Shapes the Inner Vestibule of LeuT , 2016, PLoS Comput. Biol..

[21]  M. Freissmuth,et al.  Electrogenic Binding of Intracellular Cations Defines a Kinetic Decision Point in the Transport Cycle of the Human Serotonin Transporter* , 2016, The Journal of Biological Chemistry.

[22]  E. Gouaux,et al.  X-ray structures and mechanism of the human serotonin transporter , 2016, Nature.

[23]  Lucy R Forrest,et al.  Two Na+ Sites Control Conformational Change in a Neurotransmitter Transporter Homolog* , 2015, The Journal of Biological Chemistry.

[24]  Martin K. Scherer,et al.  PyEMMA 2: A Software Package for Estimation, Validation, and Analysis of Markov Models. , 2015, Journal of chemical theory and computation.

[25]  Berk Hess,et al.  GROMACS: High performance molecular simulations through multi-level parallelism from laptops to supercomputers , 2015 .

[26]  Helgi I. Ingólfsson,et al.  Computational Lipidomics with insane: A Versatile Tool for Generating Custom Membranes for Molecular Simulations. , 2015, Journal of chemical theory and computation.

[27]  Helgi I Ingólfsson,et al.  Lipid organization of the plasma membrane. , 2014, Journal of the American Chemical Society.

[28]  S. Fuchigami,et al.  Slow dynamics of a protein backbone in molecular dynamics simulation revealed by time-structure based independent component analysis. , 2013, The Journal of chemical physics.

[29]  Eric Gouaux,et al.  X-ray structure of dopamine transporter elucidates antidepressant mechanism , 2013, Nature.

[30]  S. Kortagere,et al.  Identification of an allosteric modulator of the serotonin transporter with novel mechanism of action , 2013, Neuropharmacology.

[31]  Alexander Lyubartsev,et al.  Partial atomic charges and their impact on the free energy of solvation , 2013, J. Comput. Chem..

[32]  Alexander P Lyubartsev,et al.  Another Piece of the Membrane Puzzle: Extending Slipids Further. , 2013, Journal of chemical theory and computation.

[33]  W F Drew Bennett,et al.  Improved Parameters for the Martini Coarse-Grained Protein Force Field. , 2013, Journal of chemical theory and computation.

[34]  H. Sitte,et al.  Unifying Concept of Serotonin Transporter-associated Currents* , 2011, The Journal of Biological Chemistry.

[35]  U. Gether,et al.  SLC6 Neurotransmitter Transporters: Structure, Function, and Regulation , 2011, Pharmacological Reviews.

[36]  Elizabeth J. Denning,et al.  MDAnalysis: A toolkit for the analysis of molecular dynamics simulations , 2011, J. Comput. Chem..

[37]  Daniel S. Terry,et al.  Substrate-modulated gating dynamics in a Na+-coupled neurotransmitter transporter homolog , 2011, Nature.

[38]  Maarten G. Wolf,et al.  g_membed: Efficient insertion of a membrane protein into an equilibrated lipid bilayer with minimal perturbation , 2010, J. Comput. Chem..

[39]  R. Dror,et al.  Improved side-chain torsion potentials for the Amber ff99SB protein force field , 2010, Proteins.

[40]  E. Gouaux,et al.  A Competitive Inhibitor Traps LeuT in an Open-to-Out Conformation , 2008, Science.

[41]  Li Xie,et al.  Mechanism for alternating access in neurotransmitter transporters , 2008, Proceedings of the National Academy of Sciences.

[42]  R. Larson,et al.  The MARTINI Coarse-Grained Force Field: Extension to Proteins. , 2008, Journal of chemical theory and computation.

[43]  Jonathan A. Javitch,et al.  Mechanism of chloride interaction with neurotransmitter:sodium symporters , 2007, Nature.

[44]  M. Parrinello,et al.  Canonical sampling through velocity rescaling. , 2007, The Journal of chemical physics.

[45]  Eric Gouaux,et al.  Crystal structure of a bacterial homologue of Na+/Cl--dependent neurotransmitter transporters , 2005, Nature.

[46]  C. Grewer,et al.  Rapid substrate-induced charge movements of the GABA transporter GAT1. , 2005, Biophysical journal.

[47]  M. Reith,et al.  Synaptic uptake and beyond: the sodium- and chloride-dependent neurotransmitter transporter family SLC6 , 2004, Pflügers Archiv.

[48]  D. Hilgemann,et al.  Gat1 (Gaba:Na+:Cl−) Cotransport Function , 1999, The Journal of general physiology.

[49]  K Schulten,et al.  VMD: visual molecular dynamics. , 1996, Journal of molecular graphics.

[50]  Schuster,et al.  Separation of a mixture of independent signals using time delayed correlations. , 1994, Physical review letters.

[51]  T. Darden,et al.  Particle mesh Ewald: An N⋅log(N) method for Ewald sums in large systems , 1993 .

[52]  H. Lester,et al.  Steady states, charge movements, and rates for a cloned GABA transporter expressed in Xenopus oocytes , 1993, Neuron.

[53]  H. Lester,et al.  Cloning and expression of a rat brain GABA transporter. , 1990, Science.

[54]  B. Kanner,et al.  gamma-Aminobutyric acid transport in reconstituted preparations from rat brain: coupled sodium and chloride fluxes. , 1988, Biochemistry.

[55]  B. Kanner,et al.  Stoichiometry of sodium- and chloride-coupled gamma-aminobutyric acid transport by synaptic plasma membrane vesicles isolated from rat brain. , 1983, Biochemistry.

[56]  R. Zwanzig From classical dynamics to continuous time random walks , 1983 .

[57]  M. Parrinello,et al.  Polymorphic transitions in single crystals: A new molecular dynamics method , 1981 .

[58]  B. Kanner Active transport of gamma-aminobutyric acid by membrane vesicles isolated from rat brain. , 1978, Biochemistry.

[59]  L. Iversen,et al.  Synaptosomes: Different Populations storing Catecholamines and Gamma-aminobutyric Acid in Homogenates of Rat Brain , 1968, Nature.

[60]  J. Changeux,et al.  ON THE NATURE OF ALLOSTERIC TRANSITIONS: A PLAUSIBLE MODEL. , 1965, Journal of molecular biology.

[61]  Ian M. Kenney,et al.  MDAnalysis: A Python Package for the Rapid Analysis of Molecular Dynamics Simulations , 2016, SciPy.

[62]  Susan Schwartz,et al.  The action of γ-Aminobutyric acid on cortical neurones , 2004, Experimental Brain Research.

[63]  G. van Meer Lipids of the Golgi membrane. , 1998, Trends in cell biology.