1. Determinants of pore folding in potassium channel biogenesis
- Author
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Erin Delaney, Pooja Khanna, Carol Deutsch, LiWei Tu, and John M. Robinson
- Subjects
Models, Molecular ,Membrane potential ,Potassium Channels ,Multidisciplinary ,Sequence Homology, Amino Acid ,Molecular Sequence Data ,Biological Sciences ,Biology ,Permeation ,Potassium channel ,Protein Structure, Tertiary ,chemistry.chemical_compound ,Monomer ,Biochemistry ,chemistry ,Biophysics ,Animals ,Humans ,Electrophoresis, Polyacrylamide Gel ,Amino Acid Sequence ,Peptide sequence ,Ion channel ,Biogenesis - Abstract
Many ion channels, both selective and nonselective, have reentrant pore loops that contribute to the architecture of the permeation pathway. It is a fundamental feature of these diverse channels, regardless of whether they are gated by changes of membrane potential or by neurotransmitters, and is critical to function of the channel. Misfolding of the pore loop leads to loss of trafficking and expression of these channels on the cell surface. Mature tetrameric potassium channels contain an α-helix within the pore loop. We systematically mutated the "pore helix" residues of the channel Kv1.3 and assessed the ability of the monomer to fold into a tertiary reentrant loop. Our results show that pore loop residues form a canonical α-helix in the monomer early in biogenesis and that disruption of tertiary folding is caused by hydrophilic substitutions only along one face of this α-helix. These results provide insight into the determinants of the reentrant pore conformation, which is essential for ion channel function.
- Published
- 2014
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