posted on 2022-11-23, 18:31authored byMaryam Yekefallah, Carver A. Rasberry, Evan J. van Aalst, Holley P. Browning, Reza Amani, Derek B. Versteeg, Benjamin J. Wylie
Potassium (K+) channels are regulated in part by allosteric
communication between the helical bundle crossing, or inner gate,
and the selectivity filter, or outer gate. This network is triggered
by gating stimuli. In concert, there is an allosteric network which
is a conjugated set of interactions which correlate long-range structural
rearrangements necessary for channel function. Inward-rectifier K+ (Kir) channels favor inward K+ conductance, are
ligand-gated, and help establish resting membrane potentials. KirBac1.1
is a bacterial Kir (KirBac) channel homologous to human Kir (hKir)
channels. Additionally, KirBac1.1 is gated by the anionic phospholipid
ligand phosphatidylglycerol (PG). In this study, we use site-directed
mutagenesis to investigate residues involved in the KirBac1.1 gating
mechanism and allosteric network we previously proposed using detailed
solid-state NMR (SSNMR) measurements. Using fluorescence-based K+ and sodium (Na+) flux assays, we identified channel
mutants with impaired function that do not alter selectivity of the
channel. In tandem, we performed coarse grain molecular dynamics simulations,
observing changes in PG-KirBac1.1 interactions correlated with mutant
channel activity and contacts between the two transmembrane helices
and pore helix tied to this behavior. Lipid affinity is closely tied
to the proximity of two tryptophan residues on neighboring subunits
which lure anionic lipids to a cationic pocket formed by a cluster
of arginine residues. Thus, these simulations establish a structural
and functional basis for the role of each mutated site in the proposed
allosteric network. The experimental and simulated data provide insight
into key functional residues involved in gating and lipid allostery
of K+ channels. Our findings also have direct implications
on the physiology of hKir channels due to conservation of many of
the residues identified in this work from KirBac1.1.