N- and C-terminal cytoplasmic domains of inwardly rectifying K (Kir) channels control the ion-permeation pathway through diverse interactions with small molecules and protein ligands in the cytoplasm. Two new crystal structures of the cytoplasmic domains of Kir2.1 (Kir2.1(L)) and the G protein-sensitive Kir3.1 (Kir3.1(S)) channels in the absence of PIP(2) show the cytoplasmic ion-permeation pathways occluded by four cytoplasmic loops that form a girdle around the central pore (G-loop). Significant flexibility of the pore-facing G-loop of Kir2.1(L) and Kir3.1(S) suggests a possible role as a diffusion barrier between cytoplasmic and transmembrane pores. Consistent with this, mutations of the G-loop disrupted gating or inward rectification. Structural comparison shows a di-aspartate cluster on the distal end of the cytoplasmic pore of Kir2.1(L) that is important for modulating inward rectification. Taken together, these results suggest the cytoplasmic domains of Kir channels undergo structural changes to modulate gating and inward rectification.
Kir2.1 channels play a key role in maintaining the correct resting potential in eukaryotic cells. Recently, specific amino acid mutations in the Kir2.1 inwardly rectifying potassium channel have been found to cause Andersen's Syndrome in humans. Here, we have characterized individual Andersen's Syndrome mutants R218Q, G300V, E303K, and delta314-315 and have found multiple effects on the ability of the cytoplasmic domains in Kir2.1 channels to form proper tetrameric assemblies. For the R218Q mutation, we identified a second site mutation (T309K) that restored tetrameric assembly but not function. We successfully crystallized and solved the structure (at 2.0 A) of the N- and C-terminal cytoplasmic domains of Kir2.1-R218Q/T309K(S). This new structure revealed multiple conformations of the G-loop and CD loop, providing an explanation for channels that assemble but do not conduct ions. Interestingly, Glu303 forms both intra- and intersubunit salt bridges, depending on the conformation of the G-loop, suggesting that the E303K mutant stabilizes both closed and open G-loop conformations. In the Kir2.1-R218Q/T309K(S) structure, we discovered that the DE loop forms a hydrophobic pocket that binds 2-methyl-2,4-pentanediol, which is located near the putative G(betagamma)-activation site of Kir3 channels. Finally, we observed a potassium ion bound to the cytoplasmic domain for this class of K+ channels.
Control of surface expression of inwardly rectifying potassium (Kir) channels is important for
regulating membrane excitability. Kir2 channels have been shown to interact directly with PDZ-containing
proteins in the postsynaptic density (PSD). These scaffold proteins, such as PSD95, bind to Kir2.1 channels
via a PDZ-binding motif (T/S-x-Φ) in the C-terminal tail (SEI428). By utilizing a multidimensional solution
NMR approach, we show that the previously unresolved structure of Kir2.1 tail (residues 372−428) is
highly flexible. Using in vitro binding assays, we determined that shortening the flexible tail of Kir2.1
preceding the C-terminal region (residues 414−428) does not significantly disrupt PDZ binding. We also
investigated which amino acids in the Kir2.1 tail associated with PSD95 PDZ1,2 by NMR spectroscopy,
revealing that a stretch of 12 C-terminal amino acids is involved in interaction with both PDZ domains
(residues 417−428). Deletion of the 11 amino acids preceding the C-terminal tail, Δ414−424, completely
disrupts binding to PSD95 PDZ1,2. Therefore, the molecular interfaces formed between PDZ domains
and Kir2.1 tail involve regions outside the previously identified binding motif (SEI428) and may be important
for additional channel-specific interactions with associating PDZ-containing proteins.
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