Abstract:NaChBac, the first bacterial voltage-gated Na+(Nav) channel to be characterized, has been the prokaryotic prototype for studying the structure–function relationship of Navchannels. Discovered nearly two decades ago, the structure of NaChBac has not been determined. Here we present the single particle electron cryomicroscopy (cryo-EM) analysis of NaChBac in both detergent micelles and nanodiscs. Under both conditions, the conformation of NaChBac is nearly identical to that of the potentially inactivated NavAb. … Show more
“…We had some concerns with potential structural perturbation of these highly dynamic molecular machines by detergents. The structural similarity of rCa v 1.1 in nanodiscs and in detergent micelles, which was also observed in our recently published NaChBac, [11] alleviates this concern and consolidates the structural findings obtained from the detergent‐embedded channels. More satisfyingly, the coordination of the backbones of all resolved DHP antagonists, nifedipine, [10c] amlodipine, and RBK, is conserved regardless of the surrounding milieu of detergents or nanodiscs.…”
Section: Resultssupporting
confidence: 82%
“…The endogenous rCa v 1.1 complex isolated from the rabbit skeletal muscle was purified following our published protocols [10a, 11] . Please refer to the Supporting Information for details of nanodisc reconstitution with the membrane scaffold protein 2N2 (MSP2N2) and 1‐palmitoyl‐2‐oleoyl‐sn‐glycero‐3‐phosphocholine (POPC) (Figure 1 B and Supporting Information, Figure S1).…”
1,4‐Dihydropyridines (DHP), the most commonly used antihypertensives, function by inhibiting the L‐type voltage‐gated Ca2+ (Cav) channels. DHP compounds exhibit chirality‐specific antagonistic or agonistic effects. The structure of rabbit Cav1.1 bound to an achiral drug nifedipine reveals the general binding mode for DHP drugs, but the molecular basis for chiral specificity remained elusive. Herein, we report five cryo‐EM structures of nanodisc‐embedded Cav1.1 in the presence of the bestselling drug amlodipine, a DHP antagonist (R)‐(+)‐Bay K8644, and a titration of its agonistic enantiomer (S)‐(−)‐Bay K8644 at resolutions of 2.9–3.4 Å. The amlodipine‐bound structure reveals the molecular basis for the high efficacy of the drug. All structures with the addition of the Bay K8644 enantiomers exhibit similar inactivated conformations, suggesting that (S)‐(−)‐Bay K8644, when acting as an agonist, is insufficient to lock the activated state of the channel for a prolonged duration.
“…We had some concerns with potential structural perturbation of these highly dynamic molecular machines by detergents. The structural similarity of rCa v 1.1 in nanodiscs and in detergent micelles, which was also observed in our recently published NaChBac, [11] alleviates this concern and consolidates the structural findings obtained from the detergent‐embedded channels. More satisfyingly, the coordination of the backbones of all resolved DHP antagonists, nifedipine, [10c] amlodipine, and RBK, is conserved regardless of the surrounding milieu of detergents or nanodiscs.…”
Section: Resultssupporting
confidence: 82%
“…The endogenous rCa v 1.1 complex isolated from the rabbit skeletal muscle was purified following our published protocols [10a, 11] . Please refer to the Supporting Information for details of nanodisc reconstitution with the membrane scaffold protein 2N2 (MSP2N2) and 1‐palmitoyl‐2‐oleoyl‐sn‐glycero‐3‐phosphocholine (POPC) (Figure 1 B and Supporting Information, Figure S1).…”
1,4‐Dihydropyridines (DHP), the most commonly used antihypertensives, function by inhibiting the L‐type voltage‐gated Ca2+ (Cav) channels. DHP compounds exhibit chirality‐specific antagonistic or agonistic effects. The structure of rabbit Cav1.1 bound to an achiral drug nifedipine reveals the general binding mode for DHP drugs, but the molecular basis for chiral specificity remained elusive. Herein, we report five cryo‐EM structures of nanodisc‐embedded Cav1.1 in the presence of the bestselling drug amlodipine, a DHP antagonist (R)‐(+)‐Bay K8644, and a titration of its agonistic enantiomer (S)‐(−)‐Bay K8644 at resolutions of 2.9–3.4 Å. The amlodipine‐bound structure reveals the molecular basis for the high efficacy of the drug. All structures with the addition of the Bay K8644 enantiomers exhibit similar inactivated conformations, suggesting that (S)‐(−)‐Bay K8644, when acting as an agonist, is insufficient to lock the activated state of the channel for a prolonged duration.
“…Although the resolution was insufficient to map side chain orientation, it allowed the docking of HwTX-IV’s NMR structure onto the channel via backbone alignment. This confirmed the general orientation of HwTx-IV in the Neff and Tzakoniati models, and identified I5, F6, and W30 as residues that are immersed in the membrane [ 60 ] ( Figure 1 ). Figure 1.…”
Section: Nasptx Family Isupporting
confidence: 67%
“…Recently, Guo et al [ 60 ] attempted to produce a cryo-EM structure of HwTX-IV bound to a nanodisc-embedded bacterial Nav channel containing the extracellular halves of the human S3-S4 sequence. Although the resolution was insufficient to map side chain orientation, it allowed the docking of HwTX-IV’s NMR structure onto the channel via backbone alignment.…”
“…We threaded the sequence of NaChBac through the three PDB structures using the SWISS-MODEL software [Waterhouse, et al, 2018). The accuracy of the NaChBac model in the inactivated state was confirmed by comparing it against the recently published cryoEM structure of potentially inactivated NaChBac ( Figure S8 ) (Gao et al, 2020).…”
Propofol, one of the most commonly used intravenous general anesthetics, modulates neuronal function by interacting with ion channels. The mechanisms that link propofol binding to the modulation of distinct ion channel states, however, are not understood. To tackle this problem, we investigated prokaryotic ancestors of eukaryotic voltage-gated Na+ channels (Navs) using unbiased photoaffinity labeling with a photoacitivatable propofol analog (AziPm), electrophysiological methods and mutagenesis. The results directly demonstrate conserved propofol binding sites involving the S4 voltage sensors and the S4-S5 linkers in NaChBac and NavMs, and also suggest state-dependent changes at these sites. Then, using molecular dynamics simulations to elucidate the structural basis of propofol modulation, we show that the S4 voltage sensors and the S4-S5 linkers shape two distinct propofol binding sites in a conformation-dependent manner. These interactions help explain how propofol binding promotes activation-coupled inactivation to inhibit Nav channel function.
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