Crystal structure of the sodium-proton antiporter NhaA dimer and new mechanistic insights

Crystal structure of the sodium-proton antiporter NhaA dimer and new mechanistic insights

Sodium-proton antiporters rapidly exchange protons and sodium ions across the membrane to regulate intracellular pH, cell volume, and sodium concentration. How ion binding and release is coupled to the conformational changes associated with transport is not clear. Here, we report a crystal form of t...

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Bibliographic Details
Published in:The Journal of general physiology Vol. 144; no. 6; pp. 529 - 544
Main Authors: Lee, Chiara, Yashiro, Shoko, Dotson, David L, Uzdavinys, Povilas, Iwata, So, Sansom, Mark S P, von Ballmoos, Christoph, Beckstein, Oliver, Drew, David, Cameron, Alexander D
Format: Journal Article
Language:English
Published: United States Rockefeller University Press 01-12-2014
The Rockefeller University Press
Subjects:
Bacterial proteins
Binding Sites
Biochemistry
biokemi
Computer Simulation
Crystallization
Dimerization
E coli
Escherichia coli Proteins - chemistry
Escherichia coli Proteins - ultrastructure
Membranes
Models, Chemical
Molecular Dynamics Simulation
Physiology
Protein Binding
Protein Conformation
Protons
Sodium
Sodium - chemistry
Sodium-Hydrogen Exchangers - chemistry
Sodium-Hydrogen Exchangers - ultrastructure
Structure-Activity Relationship
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Summary:Sodium-proton antiporters rapidly exchange protons and sodium ions across the membrane to regulate intracellular pH, cell volume, and sodium concentration. How ion binding and release is coupled to the conformational changes associated with transport is not clear. Here, we report a crystal form of the prototypical sodium-proton antiporter NhaA from Escherichia coli in which the protein is seen as a dimer. In this new structure, we observe a salt bridge between an essential aspartic acid (Asp163) and a conserved lysine (Lys300). An equivalent salt bridge is present in the homologous transporter NapA, but not in the only other known crystal structure of NhaA, which provides the foundation of most existing structural models of electrogenic sodium-proton antiport. Molecular dynamics simulations show that the stability of the salt bridge is weakened by sodium ions binding to Asp164 and the neighboring Asp163. This suggests that the transport mechanism involves Asp163 switching between forming a salt bridge with Lys300 and interacting with the sodium ion. pKa calculations suggest that Asp163 is highly unlikely to be protonated when involved in the salt bridge. As it has been previously suggested that Asp163 is one of the two residues through which proton transport occurs, these results have clear implications to the current mechanistic models of sodium-proton antiport in NhaA.
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C. Lee, S. Yashiro, and D.L. Dotson contributed equally to this work.
ISSN:0022-1295
1540-7748
1540-7748
DOI:10.1085/jgp.201411219