Francis I. Valiyaveetil

Ion Selectivity in a Semisynthetic K+ Channel Locked in the Conductive Conformation

Potassium channels are K+-selective protein pores in cell membrane. The selectivity filter is the functional unit that allows K+ channels to distinguish potassium (K+) and sodium (Na+) ions. The filters structure depends on whether K+ or Na+ ions are bound inside it. We synthesized a K+ channel containing the d-enantiomer of alanine in place of a conserved glycine and found by x-ray crystallography that its filter maintains the K+ (conductive) structure in the presence of Na+ and very low concentrations of K+. This channel conducts Na+ in the absence of K+ but not in the presence of K+. These findings demonstrate that the ability of the channel to adapt its structure differently to K+ and Na+ is a fundamental aspect of ion selectivity, as is the ability of multiple K+ ions to compete effectively with Na+ for the conductive filter.

Semisynthetic K+ channels show that the constricted conformation of the selectivity filter is not the C-type inactivated state

Significance C-type inactivation is a conformational change at the selectivity filter, the ion binding site in a K+ channel that renders it nonconductive. C-type inactivation is important in modulating cellular excitability. Previous studies have suggested a “constricted conformation” for the selectivity filter in the C-type inactivated state. Here, we use protein semisynthesis to introduce unnatural amino acids into the selectivity filter to block it from attaining the constricted conformation. We show that blocking the constricted conformation does not affect C-type inactivation. This study therefore suggests that the constricted conformation of the selectivity filter is not the C-type inactivated state in a K+ channel. The study also highlights ways in which chemical synthesis can be used to manipulate large integral membrane proteins. C-type inactivation of K+ channels plays a key role in modulating cellular excitability. During C-type inactivation, the selectivity filter of a K+ channel changes conformation from a conductive to a nonconductive state. Crystal structures of the KcsA channel determined at low K+ or in the open state revealed a constricted conformation of the selectivity filter, which was proposed to represent the C-type inactivated state. However, structural studies on other K+ channels do not support the constricted conformation as the C-type inactivated state. In this study, we address whether the constricted conformation of the selectivity filter is in fact the C-type inactivated state. The constricted conformation can be blocked by substituting the first conserved glycine in the selectivity filter with the unnatural amino acid d-Alanine. Protein semisynthesis was used to introduce d-Alanine into the selectivity filters of the KcsA channel and the voltage-gated K+ channel KvAP. For semisynthesis of the KvAP channel, we developed a modular approach in which chemical synthesis is limited to the selectivity filter whereas the rest of the protein is obtained by recombinant means. Using the semisynthetic KcsA and KvAP channels, we show that blocking the constricted conformation of the selectivity filter does not prevent inactivation, which suggests that the constricted conformation is not the C-type inactivated state.

Instantaneous ion configurations in the K+ ion channel selectivity filter revealed by 2D IR spectroscopy

Potassium channels are responsible for the selective permeation of K+ ions across cell membranes. K+ ions permeate in single file through the selectivity filter, a narrow pore lined by backbone carbonyls that compose four K+ binding sites. Here, we report on the two-dimensional infrared (2D IR) spectra of a semisynthetic KcsA channel with site-specific heavy (13C18O) isotope labels in the selectivity filter. The ultrafast time resolution of 2D IR spectroscopy provides an instantaneous snapshot of the multi-ion configurations and structural distributions that occur spontaneously in the filter. Two elongated features are resolved, revealing the statistical weighting of two structural conformations. The spectra are reproduced by molecular dynamics simulations of structures with water separating two K+ ions in the binding sites, ruling out configurations with ions occupying adjacent sites.

Modular Strategy for the Semisynthesis of a K+ Channel: Investigating Interactions of the Pore Helix

Chemical synthesis is a powerful method for precise modification of the structural and electronic properties of proteins. The difficulties in the synthesis and purification of peptides containing transmembrane segments have presented obstacles to the chemical synthesis of integral membrane proteins. Here, we present a modular strategy for the semisynthesis of integral membrane proteins in which solid-phase peptide synthesis is limited to the region of interest, while the rest of the protein is obtained by recombinant means. This modular strategy considerably simplifies the synthesis and purification steps that have previously hindered the chemical synthesis of integral membrane proteins. We develop a SUMO fusion and proteolysis approach for obtaining the N-terminal cysteine containing membrane-spanning peptides required for the semisynthesis. We demonstrate the feasibility of the modular approach by the semisynthesis of full-length KcsA K(+) channels in which only regions of interest, such as the selectivity filter or the pore helix, are obtained by chemical synthesis. The modular approach is used to investigate the hydrogen bond interactions of a tryptophan residue in the pore helix, tryptophan 68, by substituting it with the isosteric analogue, beta-(3-benzothienyl)-l-alanine (3BT). A functional analysis of the 3BT mutant channels indicates that the K(+) conduction and selectivity of the 3BT mutant channels are similar to those of the wild type, but the mutant channels show a 3-fold increase in Rb(+) conduction. These results suggest that the hydrogen bond interactions of tryptophan 68 are essential for optimizing the selectivity filter for K(+) conduction over Rb(+) conduction.

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

Significance C-type inactivation is a gating process that takes place at the selectivity filter of K+ channels. C-type inactivation is important in regulating cellular excitability. A defining characteristic of C-type inactivation is a dependence on the permeant ion, but the underlying mechanism is not known. We use protein backbone mutagenesis to alter ion binding at specific sites in the selectivity filter and determine the effect on inactivation. We show that C-type inactivation is linked to ion occupancy at a specific site in the selectivity filter. This study underscores the utility of unnatural mutagenesis for investigating the mechanisms of channel function. Furthermore, permeant ions modulate function in many channel families; therefore, the approaches used in this study are generally applicable. 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 KvAP 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.

Ion-binding properties of a K+ channel selectivity filter in different conformations.

Significance The selectivity filter of K+ channels is responsible for their exquisite ion selectivity. This region is also responsible for C-type inactivation, a regulatory process in many voltage-dependent K+ channels. Although the functional properties of inactivated channels have been known for decades, the first potential glimpse of their structure emerged from crystal structures of a constricted selectivity filter in an open channel. However, recent studies challenged the suggestion that the constricted selectivity filter is the inactivated structure, leaving open the question of what the inactivated structure looks like. Here, we provide evidence that the thermodynamic properties of the selectivity filter in an inactivated channel are more similar to properties of the conductive channel rather than the constricted open channel. K+ channels are membrane proteins that selectively conduct K+ ions across lipid bilayers. Many voltage-gated K+ (KV) channels contain two gates, one at the bundle crossing on the intracellular side of the membrane and another in the selectivity filter. The gate at the bundle crossing is responsible for channel opening in response to a voltage stimulus, whereas the gate at the selectivity filter is responsible for C-type inactivation. Together, these regions determine when the channel conducts ions. The K+ channel from Streptomyces lividians (KcsA) undergoes an inactivation process that is functionally similar to KV channels, which has led to its use as a practical system to study inactivation. Crystal structures of KcsA channels with an open intracellular gate revealed a selectivity filter in a constricted conformation similar to the structure observed in closed KcsA containing only Na+ or low [K+]. However, recent work using a semisynthetic channel that is unable to adopt a constricted filter but inactivates like WT channels challenges this idea. In this study, we measured the equilibrium ion-binding properties of channels with conductive, inactivated, and constricted filters using isothermal titration calorimetry (ITC). EPR spectroscopy was used to determine the state of the intracellular gate of the channel, which we found can depend on the presence or absence of a lipid bilayer. Overall, we discovered that K+ ion binding to channels with an inactivated or conductive selectivity filter is different from K+ ion binding to channels with a constricted filter, suggesting that the structures of these channels are different.

In vitro folding of KvAP, a voltage gated K+ channel

In this contribution, we report in vitro folding of the archaebacterial voltage-gated K(+) channel, K(v)AP. We show that in vitro folding of the K(v)AP channel from the extensively unfolded state requires lipid vesicles and that the refolded channel is biochemically and functionally similar to the native channel. The in vitro folding process is slow at room temperature, and the folding yield depends on the composition of the lipid bilayer. The major factor influencing refolding is temperature, and almost quantitative refolding of the K(v)AP channel is observed at 80 °C. To differentiate between insertion into the bilayer and folding within the bilayer, we developed a cysteine protection assay. Using this assay, we demonstrate that insertion of the unfolded protein into the bilayer is relatively fast at room temperature and independent of lipid composition, suggesting that temperature and bilayer composition influence folding within the bilayer. Further, we demonstrate that in vitro folding provides an effective method for obtaining high yields of the native channel. Our studies suggest that the K(v)AP channel provides a good model system for investigating the folding of a multidomain integral membrane protein.

Individual Ion Binding Sites in the K+ Channel Play Distinct Roles in C-type Inactivation and in Recovery from Inactivation

The selectivity filter of K(+) channels contains four ion binding sites (S1-S4) and serves dual functions of discriminating K(+) from Na(+) and acting as a gate during C-type inactivation. C-type inactivation is modulated by ion binding to the selectivity filter sites, but the underlying mechanism is not known. Here we evaluate how the ion binding sites in the selectivity filter of the KcsA channel participate in C-type inactivation and in recovery from inactivation. We use unnatural amide-to-ester substitutions in the protein backbone to manipulate the S1-S3 sites and a side-chain substitution to perturb the S4 site. We develop an improved semisynthetic approach for generating these amide-to-ester substitutions in the selectivity filter. Our combined electrophysiological and X-ray crystallographic analysis of the selectivity filter mutants show that the ion binding sites play specific roles during inactivation and provide insights into the structural changes at the selectivity filter during C-type inactivation.

Incorporation of Non-Canonical Amino Acids

In this chapter we discuss the strengths, caveats and technical considerations of three approaches for reprogramming the chemical composition of selected amino acids within a membrane protein. In vivo nonsense suppression in the Xenopus laevis oocyte, evolved orthogonal tRNA and aminoacyl-tRNA synthetase pairs and protein ligation for biochemical production of semisynthetic proteins have been used successfully for ion channel and receptor studies. The level of difficulty for the application of each approach ranges from trivial to technically demanding, yet all have untapped potential in their application to membrane proteins.

Studies of ion channels using expressed protein ligation

Expressed protein ligation (EPL) is a semisynthetic technique for the chemoselective ligation of a synthetic peptide to a recombinant peptide that results in a native peptide bond at the ligation site. EPL therefore allows us to engineer proteins with chemically defined, site-specific modifications. While EPL has been used mainly in investigations of soluble proteins, in recent years it has been increasingly used in investigations of integral membrane proteins. These include studies on the KcsA K(+) channel, the non-selective cation channel NaK, and the porin OmpF. These studies are discussed in this review.