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2K1E

NMR studies of a channel protein without membranes: structure and dynamics of water-solubilized KcsA

Summary for 2K1E
Entry DOI10.2210/pdb2k1e/pdb
Related2KB1
NMR InformationBMRB: 15677
Descriptorwater soluble analogue of potassium channel, KcsA (1 entity in total)
Functional Keywordshomotetramer, ion transport, ionic channel, membrane, transmembrane, transport, voltage-gated channel, membrane protein
Biological sourceEscherichia coli
Total number of polymer chains4
Total formula weight45618.51
Authors
Ma, D.,Xu, Y.,Tillman, T.,Tang, P.,Meirovitch, E.,Eckenhoff, R.,Carnini, A. (deposition date: 2008-02-29, release date: 2008-11-11, Last modification date: 2024-05-29)
Primary citationMa, D.,Tillman, T.S.,Tang, P.,Meirovitch, E.,Eckenhoff, R.,Carnini, A.,Xu, Y.
NMR studies of a channel protein without membranes: structure and dynamics of water-solubilized KcsA.
Proc.Natl.Acad.Sci.Usa, 105:16537-16542, 2008
Cited by
PubMed Abstract: Structural studies of polytopic membrane proteins are often hampered by the vagaries of these proteins in membrane mimetic environments and by the difficulties in handling them with conventional techniques. Designing and creating water-soluble analogues with preserved native structures offer an attractive alternative. We report here solution NMR studies of WSK3, a water-soluble analogue of the potassium channel KcsA. The WSK3 NMR structure (PDB ID code 2K1E) resembles the KcsA crystal structures, validating the approach. By more stringent comparison criteria, however, the introduction of several charged residues aimed at improving water solubility seems to have led to the possible formations of a few salt bridges and hydrogen bonds not present in the native structure, resulting in slight differences in the structure of WSK3 relative to KcsA. NMR dynamics measurements show that WSK3 is highly flexible in the absence of a lipid environment. Reduced spectral density mapping and model-free analyses reveal dynamic characteristics consistent with an isotropically tumbling tetramer experiencing slow (nanosecond) motions with unusually low local ordering. An altered hydrogen-bond network near the selectivity filter and the pore helix, and the intrinsically dynamic nature of the selectivity filter, support the notion that this region is crucial for slow inactivation. Our results have implications not only for the design of water-soluble analogues of membrane proteins but also for our understanding of the basic determinants of intrinsic protein structure and dynamics.
PubMed: 18948596
DOI: 10.1073/pnas.0805501105
PDB entries with the same primary citation
Experimental method
SOLUTION NMR
Structure validation

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