Permeation mechanisms through the selectivity filter and the open helix bundle crossing gate of GIRK2

Structural insights in the permeation mechanism of an activated GIRK2 channel

G protein-gated inwardly rectifying potassium (GIRK) channels play a significant role in physiopathology by the regulation of cell excitability. This regulation depends on the K+ ion conduction induced by structural constrictions: the selectivity filters (SFs), helix bundle crossings (HBCs), and G-loop gates. To explore why no permeation occurred when the constrictions were kept in the open state, a 4-K+-related occupancy mechanism was proposed. Unfortunately, this hypothesis was neither assessed, nor was the energetic characteristics presented. To identify the permeation mechanism on an atomic level, all-atom molecular dynamic (MD) simulations and a coupled quantum mechanics and molecular mechanics (QM/MM) method were used for the GIRK2 mutant R201A. It was found that the R201A had a moderate conductive capability in the presence of PIP2. Furthermore, the 4-K+ group of ions was found to dominate the conduction through the activated HBC gate. This shielding-like mechanism was assessed by the potential energy barrier along the conduction pathway. Mutation studies did further support the assumption that E152 was responsible for the mechanism. Moreover, E152 was most probably facilitating the inflow of ions from the SF to the cavity. On the contrary, N184 had no remarkable effect on this mechanism, except for the conduction efficiency. These findings highlighted the necessity of a multi-ion distribution for the conduction to take place, and indicated that the K+ migration was not only determined by the channel conductive state in the GIRK channel. The here presented multi-ion permeation mechanism may help to provide an effective way to regulate the channelopathies.

Use of a Molecular Switch Probe to Activate or Inhibit GIRK1 Heteromers In Silico Reveals a Novel Gating Mechanism

G protein-gated inwardly rectifying K⁺ (GIRK) channels form highly active heterotetramers in the body, such as in neurons (GIRK1/GIRK2 or GIRK1/2) and heart (GIRK1/GIRK4 or GIRK1/4). Based on three-dimensional atomic resolution structures for GIRK2 homotetramers, we built heterotetrameric GIRK1/2 and GIRK1/4 models in a lipid bilayer environment. By employing a urea-based activator ML297 and its molecular switch, the inhibitor GAT1587, we captured channel gating transitions and K⁺ ion permeation in sub-microsecond molecular dynamics (MD) simulations. This allowed us to monitor the dynamics of the two channel gates (one transmembrane and one cytosolic) as well as their control by the required phosphatidylinositol bis 4-5-phosphate (PIP₂). By comparing differences in the two trajectories, we identify three hydrophobic residues in the transmembrane domain 1 (TM1) of GIRK1, namely, F87, Y91, and W95, which form a hydrophobic wire induced by ML297 and de-induced by GAT1587 to orchestrate channel gating. This includes bending of the TM2 and alignment of a dipole of two acidic GIRK1 residues (E141 and D173) in the permeation pathway to facilitate K⁺ ion conduction. Moreover, the TM movements drive the movement of the Slide Helix relative to TM1 to adjust interactions of the CD-loop that controls the gating of the cytosolic gate. The simulations reveal that a key basic residue that coordinates PIP₂ to stabilize the pre-open and open states of the transmembrane gate flips in the inhibited state to form a direct salt-bridge interaction with the cytosolic gate and destabilize its open state.

A selectivity filter mutation provides insights into gating regulation of a K+ channel

G-protein coupled inwardly rectifying potassium (GIRK) channels are key players in inhibitory neurotransmission in heart and brain. We conducted molecular dynamics simulations to investigate the effect of a selectivity filter (SF) mutation, G154S, on GIRK2 structure and function. We observe mutation-induced loss of selectivity, changes in ion occupancy and altered filter geometry. Unexpectedly, we reveal aberrant SF dynamics in the mutant to be correlated with motions in the binding site of the channel activator Gβγ. This coupling is corroborated by electrophysiological experiments, revealing that GIRK2_wt activation by Gβγ reduces the affinity of Ba²⁺ block. We further present a functional characterization of the human GIRK2_G154S mutant validating our computational findings. This study identifies an allosteric connection between the SF and a crucial activator binding site. This allosteric gating mechanism may also apply to other potassium channels that are modulated by accessory proteins.

Gly selectivity filter (TIGYGYR) mutant of the GIRK2 channel causes rare but severe neurological disorder called the Keppen-Lubinsky syndrome. Here, the authors explore the molecular mechanism of action of this glycine to serine mutant causing disease and identify an allosteric connection between the selectivity filter and a crucial activator binding site.