Thilo Focken

Structural basis of Nav1.7 inhibition by an isoform-selective small-molecule antagonist.

A channel involved in pain perception Voltage-gated sodium (Nav) channels propagate electrical signals in muscle cells and neurons. In humans, Nav1.7 plays a key role in pain perception. It is challenging to target a particular Nav isoform; however, arylsulfonamide antagonists selective for Nav1.7 have been reported recently. Ahuja et al. characterized the binding of these small molecules to human Nav channels. To further investigate the mechanism, they engineered a bacterial Nav channel to contain features of the Nav1.7 voltage-sensing domain that is targeted by the antagonist and determined the crystal structure of the chimera bound to an inhibitor. The structure gives insight into the mechanism of voltage sensing and will enable the design of more-selective Nav channel antagonists. Science, this issue p. 10.1126/science.aac5464 Structural studies give insight into how a human sodium channel involved in pain perception can be selectively inhibited. INTRODUCTION Voltage-gated sodium (Nav) channels open and close ion-selective pores in response to changes in membrane potential, and this gating underlies the generation of action potentials. Nav channels are large membrane proteins that contain four peripheral voltage-sensor domains (VSD1–4) that influence the functional state of the central ion-conducting pore. Mutations within the nine human Nav channel isoforms are associated with migraine (Nav1.1), epilepsy (Nav1.1–Nav1.3, Nav1.6), pain (Nav1.7–Nav1.9), cardiac (Nav1.5), and muscle paralysis (Nav1.4) syndromes. Accordingly, Nav channel blockers are used for the treatment of many neurological and cardiovascular disorders. These drugs bind within the central pore domain and generally lack isoform selectivity owing to the high sequence conservation found among Nav channels, limiting their therapeutic utility. In this study, we focused on a recently identified class of isoform-selective small-molecule antagonists that target a unique binding site on the fourth voltage-sensor domain, VSD4. Here we report the structural determination of such small-molecule aryl sulfonamide antagonists in complex with human Nav1.7 VSD4. Our studies demonstrate how this important new class of gating modifier engages VSD4 to inhibit Nav channel activity through a “voltage-sensor trapping” mechanism. RATIONALE For structural studies, we devised a novel protein-engineering strategy that overcomes the technical complexities of producing full-length human Nav channels. Exploiting the evolutionary relationship between human and bacterial Nav channels, we fused portions of Nav1.7 VSD4 onto the bacterial channel NavAb. Using ligand-binding assays and alanine-scanning mutagenesis, we demonstrated that the antagonist binding site present in the human Nav1.7 channel is preserved within this human VSD4-NavAb chimeric channel. This chimeric construct allowed purification, crystallization, and structure determination of potent aryl sulfonamide antagonists in complex with the human Nav1.7 VSD4 binding site. RESULTS Functional studies using patch-clamp electrophysiology revealed that aryl sulfonamide inhibitors bind with high affinity to an isoform-selective and extracellularly accessible site on VSD4. These inhibitors show a high level of state dependence, potently blocking human Nav1.7 only when VSD4 is in its activated conformation. Our crystallographic studies revealed that the anionic warhead from the aryl sulfonamide inhibitors directly engages the fourth gating charge residue (R4) on the voltage-sensing S4 helix, effectively trapping VSD4 in its activated state. Isoform selectivity is achieved by inhibitor interactions with nonconserved residues found on the S2 and S3 transmembrane helices. The drug receptor site is partially submerged within the membrane bilayer, and a peripherally bound phospholipid was observed to form a tripartite complex with the antagonist and channel. CONCLUSION A new crystallization strategy has enabled the structural determination of VSD4 from human Nav1.7 in complex with potent, state-dependent, isoform-selective small-molecule antagonists. Mechanistically, inhibitor binding traps VSD4 in an activated conformation, which stabilizes a nonconductive state of the channel, and likely prevents recovery from inactivation. Unique phospholipid interactions and an exposed inhibitor binding site expand the importance of the membrane bilayer in ion channel biology. We anticipate that these structures will enable drug design efforts aimed at other voltage-gated ion channels and may accelerate the development of new treatments for pain that selectively target Nav1.7. Drug binding sites in sodium channels. (Left) Top-view model of human Nav1.7. When open, sodium passes through the channel. Blocking drugs lacking isoform selectivity bind to a conserved site within the central pore. Isoform-selective inhibitors bind to a distinct site on VSD4. (Right) Strategy for Nav1.7 crystallography. Portions of Nav1.7 VSD4 were grafted onto a tetrameric channel (NavAb) and crystallized. (Inset) Side view of aryl sulfonamide binding site with the S4 helix and arginine gating charges highlighted pink. Voltage-gated sodium (Nav) channels propagate action potentials in excitable cells. Accordingly, Nav channels are therapeutic targets for many cardiovascular and neurological disorders. Selective inhibitors have been challenging to design because the nine mammalian Nav channel isoforms share high sequence identity and remain recalcitrant to high-resolution structural studies. Targeting the human Nav1.7 channel involved in pain perception, we present a protein-engineering strategy that has allowed us to determine crystal structures of a novel receptor site in complex with isoform-selective antagonists. GX-936 and related inhibitors bind to the activated state of voltage-sensor domain IV (VSD4), where their anionic aryl sulfonamide warhead engages the fourth arginine gating charge on the S4 helix. By opposing VSD4 deactivation, these compounds inhibit Nav1.7 through a voltage-sensor trapping mechanism, likely by stabilizing inactivated states of the channel. Residues from the S2 and S3 helices are key determinants of isoform selectivity, and bound phospholipids implicate the membrane as a modulator of channel function and pharmacology. Our results help to elucidate the molecular basis of voltage sensing and establish structural blueprints to design selective Nav channel antagonists.

Discovery of Aryl Sulfonamides as Isoform-Selective Inhibitors of NaV1.7 with Efficacy in Rodent Pain Models

We report on a novel series of aryl sulfonamides that act as nanomolar potent, isoform-selective inhibitors of the human sodium channel hNaV1.7. The optimization of these inhibitors is described. We aimed to improve potency against hNaV1.7 while minimizing off-target safety concerns and generated compound 3. This agent displayed significant analgesic effects in rodent models of acute and inflammatory pain and demonstrated that binding to the voltage sensor domain 4 site of NaV1.7 leads to an analgesic effect in vivo. Our findings corroborate the importance of hNaV1.7 as a drug target for the treatment of pain.

Design of Conformationally Constrained Acyl Sulfonamide Isosteres: Identification of N-([1,2,4]Triazolo[4,3-a]pyridin-3-yl)methane-sulfonamides as Potent and Selective hNaV1.7 Inhibitors for the Treatment of Pain

The sodium channel NaV1.7 has emerged as a promising target for the treatment of pain based on strong genetic validation of its role in nociception. In recent years, a number of aryl and acyl sulfonamides have been reported as potent inhibitors of NaV1.7, with high selectivity over the cardiac isoform NaV1.5. Herein, we report on the discovery of a novel series of N-([1,2,4]triazolo[4,3- a]pyridin-3-yl)methanesulfonamides as selective NaV1.7 inhibitors. Starting with the crystal structure of an acyl sulfonamide, we rationalized that cyclization to form a fused heterocycle would improve physicochemical properties, in particular lipophilicity. Our design strategy focused on optimization of potency for block of NaV1.7 and human metabolic stability. Lead compounds 10, 13 (GNE-131), and 25 showed excellent potency, good in vitro metabolic stability, and low in vivo clearance in mouse, rat, and dog. Compound 13 also displayed excellent efficacy in a transgenic mouse model of induced pain.