Using protein backbone mutagenesis to dissect the link between ion occupancy and C-type inactivation in K+ channels

K⁺ channels distinguish K⁺ from Na⁺ in the selectivity filter, which consists of four ion-binding sites (S1–S4, extracellular to intracellular) that are built mainly using the carbonyl oxygens from the protein backbone. In addition to ionic discrimination, the selectivity filter regulates the flow of ions across the membrane in a gating process referred to as C-type inactivation. A characteristic of C-type inactivation is a dependence on the permeant ion, but the mechanism by which permeant ions modulate C-type inactivation is not known. To investigate, we used amide-to-ester substitutions in the protein backbone of the selectivity filter to alter ion binding at specific sites and determined the effects on inactivation. The amide-to-ester substitutions in the protein backbone were introduced using protein semisynthesis or in vivo nonsense suppression approaches. We show that an ester substitution at the S1 site in the KcsA channel does not affect inactivation whereas ester substitutions at the S2 and S3 sites dramatically reduce inactivation. We determined the structure of the KcsA S2 ester mutant and found that the ester substitution eliminates K⁺ binding at the S2 site. We also show that an ester substitution at the S2 site in the K_vAP channel has a similar effect of slowing inactivation. Our results link C-type inactivation to ion occupancy at the S2 site. Furthermore, they suggest that the differences in inactivation of K⁺ channels in K⁺ compared with Rb⁺ are due to different ion occupancies at the S2 site.Potassium channels are a ubiquitous family of integral membrane proteins that facilitate the selective conduction of K⁺ ions across cellular membranes (1). K⁺ selectivity is achieved by a structural element in the K⁺ channel pore called the selectivity filter (2). The selectivity filter consists of four sequential ion-binding sites (labeled S1–S4, from the outside to inside) that are built using protein backbone carbonyl oxygen atoms and the threonine side chain from the protein sequence T-V-G-Y-G (Fig. 1A) (4, 5).Open in a separate windowFig. 1.Ester substitutions in the selectivity filter of the KcsA channel. (A) Close-up view of the selectivity filter of the wild-type KcsA channel Protein Data Bank (PDB): 1K4C]. Two opposite subunits are shown in stick representation, and the K⁺ ions bound are shown as purple spheres. The amide bonds (1′–4′) and the ion-binding sites in the selectivity filter (S1–S4) are labeled. (B) Macroscopic currents for the KcsA channels were elicited at +100 mV by a rapid change in pH from 7.5 to 3.0. (C) Single-channel currents recorded at steady-state conditions at pH 3.0. The pH 3.0 solution is 10 mM succinate, 200 mM KCl, and the pH 7.5 solution is 10 mM Hepes–KOH, 200 mM KCl. The data for KcsA^WT are from ref. 3.In addition to selective conduction of K⁺, the selectivity filter acts as a gate to regulate the flow of ions through the pore (6–8). During this gating process, conformational changes at the selectivity filter convert it from a conductive to a nonconductive state. In voltage-gated K⁺ (K_v) channels, this gating process is referred to as C-type inactivation (9). C-type inactivation is a physiologically important process as it plays a direct role in regulating neuronal firing and in pacing cardiac action potentials (8). The KcsA K⁺ channel from Streptomyces lividans undergoes an inactivation process that is functionally similar to C-type inactivation in a eukaryotic K_v channel (10–13). As the KcsA channel is easily amenable to structural studies, it has become an important model system for understanding the structure of the selectivity filter in the C-type–inactivated state and the forces that drive inactivation (14, 15).One of the hallmarks of C-type inactivation is a dependence on the permeant ion (6, 7). The rate of C-type inactivation decreases when the K⁺ concentration is increased or when the permeant ion is changed from K⁺ to Rb⁺ (16, 17). Crystallographic studies on K⁺ channels have shown that a change in the permeant ion or its concentration results in changes in the ion occupancy at the binding sites in the selectivity filter (18, 19). For example, K⁺ and Rb⁺ at similar concentrations show different occupancies at the ion-binding sites, and the channel exhibits different rates of inactivation in K⁺ compared with Rb⁺ (3, 16, 20), which suggests a link between ion occupancy at the selectivity filter and inactivation (21, 22). The influence of permeant ions on inactivation has been proposed to arise from a “foot in the door”-like effect in which ion binding at a specific site prevents inactivation, similar to the presence of a foot in the doorway that prevents a door from closing (16, 23). The binding site responsible for the foot in the door effect is suspected to be at the extracellular side of the channel, but the exact location of the binding site, whether in the selectivity filter or at the extracellular mouth of the filter, is not known (6).In this study, we investigate this link between ion binding at the selectivity filter and inactivation. The approach that we use is to alter ion binding at the selectivity filter sites and to determine the effect on inactivation. The S1–S3 ion-binding sites in the selectivity filter are constructed by backbone carbonyl oxygens. Therefore, conventional site-directed mutagenesis does not allow us to alter these sites. Instead, we use chemical synthesis and nonsense suppression approaches to introduce amide-to-ester substitutions in the protein backbone to perturb ion binding to specific sites in the selectivity filter (24, 25).Amide-to-ester substitutions have previously been used to engineer the protein backbone for studies on protein stability and folding (26). Ester bonds are isosteric to amide bonds but have altered hydrogen-bonding properties and reduced electronegativity at the carbonyl oxygen (27). This reduction in the electronegativity of the carbonyl oxygen, by roughly one-half compared with an amide bond, perturbs ion binding to the selectivity filter. Amide-to-ester substitutions have previously been reported in the selectivity filters of the Kir2.1 and the KcsA K⁺ channels (28, 29). In the Kir2.1 channel, an ester substitution for the 3′ amide bond (see Fig. 1A for nomenclature) was found to reduce channel conductance and to produce distinct subconductance levels. In the KcsA channel, an ester substitution for the 1′ amide bond was found to reduce channel conductance, and a crystal structure of the ester mutant showed that the ester substitution decreased ion occupancy at the S1 site. Neither of these studies examined the effect of the ester substitutions on inactivation.Here we substitute the 1′, 2′, and 3′ amide bonds in the selectivity filter of the KcsA K⁺ channel with esters and investigate the effect on inactivation. We determine the crystal structure of the 2′ ester mutant of the KcsA channel to examine the effect of the ester substitution on the structure and ion occupancy of the selectivity filter. We also investigate the effect of an ester substitution at the 2′ amide bond in the selectivity filter on inactivation in the voltage-gated K⁺ channel, K_vAP. Our results show that the S1 and S2 sites in the selectivity filter do not act as the foot in the door sites to prevent inactivation. Unexpectedly, we find that a lack of ion binding at the S2 site reduces inactivation.