The Pore, not Cytoplasmic Domains, Underlies Inactivation in a Prokaryotic Sodium Channel

Pavlov, Evgeny; Bladen, Chris; Winkfein, Robert J.; Diao, Catherine; Dhaliwal, Perry; French, Robert J.

doi:10.1529/biophysj.104.056994

Cited by 88 publications

(98 citation statements)

References 40 publications

(53 reference statements)

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“…C-type inactivation has been explained by conformational changes around the selectivity filter of the channel (23)(24)(25). These conformational changes, which cause the selectivity filter to collapse, act as an inactivation gate.…”

Section: Discussionmentioning

confidence: 99%

“…Although C-type inactivation is common in tetrameric cation channels, its molecular mechanism remains unclear. It has been proposed that C-type inactivation may be related to a collapse of the selectivity filter (23)(24)(25). Prokaryotic Na V s lack an obvious cytoplasmic N-type inactivation peptide, and inactivation may thus only occur through the C-type inactivation mechanism (25,26).…”

mentioning

confidence: 99%

“…It has been proposed that C-type inactivation may be related to a collapse of the selectivity filter (23)(24)(25). Prokaryotic Na V s lack an obvious cytoplasmic N-type inactivation peptide, and inactivation may thus only occur through the C-type inactivation mechanism (25,26). Furthermore, comparative studies and mutational analysis of these new Na V homologues provide evidence that the rate of C-type inactivation is affected by the residues of helix S6.…”

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confidence: 99%

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Comparative Study of the Gating Motif and C-type Inactivation in Prokaryotic Voltage-gated Sodium Channels

Irie

Kitagawa

Nagura

et al. 2010

Journal of Biological Chemistry

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Prokaryotic voltage-gated sodium channels (Na V s) are homotetramers and are thought to inactivate through a single mechanism, named C-type inactivation. Here we report the voltage dependence and inactivation rate of the NaChBac channel from Bacillus halodurans, the first identified prokaryotic Na V , as well as of three new homologues cloned from Bacillus licheniformis (Na V BacL), Shewanella putrefaciens (Na V SheP), and Roseobacter denitrificans (Na V RosD). We found that, although activated by a lower membrane potential, Na V BacL inactivates as slowly as NaChBac. Na V SheP and Na V RosD inactivate faster than NaChBac. Mutational analysis of helix S6 showed that residues corresponding to the "glycine hinge" and "PXP motif" in voltage-gated potassium channels are not obligatory for channel gating in these prokaryotic Na V s, but mutations in the regions changed the inactivation rates. Mutation of the region corresponding to the glycine hinge in Na V BacL (A214G), Na V SheP (A216G), and NaChBac (G219A) accelerated inactivation in these channels, whereas mutation of glycine to alanine in the lower part of helix S6 in NaChBac (G229A), Na V BacL (G224A), and Na V RosD (G217A) reduced the inactivation rate. These results imply that activation gating in prokaryotic Na V s does not require gating motifs and that the residues of helix S6 affect C-type inactivation rates in these channels.Voltage-gated sodium channels (Na V s) 3 generate the rapid upstroke of action potentials in nerve cell axons (1). In mammalian Na V s, the channel is formed by the ␣-subunit, which comprises four repeats of six-transmembrane segments, with each repeat consisting of 300 -400 amino acids. The ␣-subunit carries several glycosylation sites and co-assembles with auxiliary subunits to form the native channel (2, 3). The only structural information on Na V s available to date is a density map of the Na V from the electric organ of the electric eel determined by cryoelectron microscopy (4). Due to its limited resolution of 19 Å, the density map did not provide insights into the gating or sodium selectivity.The first prokaryotic Na V , NaChBac, was cloned from Bacillus halodurans (5). Subsequently, three more prokaryotic sodium channels were cloned and characterized (6, 7). All studied prokaryotic Na V s form homotetramers with a structure thought to be similar to that of some potassium channels with known structures (8 -10). Furthermore, because the proteins could be expressed in large amounts in Escherichia coli and purified by metal chelate affinity chromatography (5, 7, 11), they are promising candidates for high resolution structure determination and structure-function analyses.The physiological role of prokaryotic Na V s may be related to pH homeostasis, motility, and chemotaxis (6, 12). Searching bacterial genomic data bases, we found 26 sequences of putative NaChBac homologues from bacteria living in various environments. We were able to clone the putative Na V genes from three of these bacteria, Bacillus licheniformis, Shewanella pu...

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Comparative Study of the Gating Motif and C-type Inactivation in Prokaryotic Voltage-gated Sodium Channels

Irie

Kitagawa

Nagura

et al. 2010

Journal of Biological Chemistry

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“…Sevoflurane enters the four equivalent extracellular sites quickly during the anesthetic partitioning phase, and remains there for the duration of the simulations. The extracellular region of NaChBac could influence the conformation of the selectivity filter to regulate P/C type inactivation (28,30). Therefore, sevoflurane interaction at the extracellular site could alter the stability of the filter region.…”

Section: Significancementioning

confidence: 99%

“…Although crystal structures are not yet reported, the bacterial Na + channel NaChBac has been extensively characterized by electrophysiology (22,(28)(29)(30)(31)(32)(33)(34)(35)(36). Additionally NaChBac exhibits conserved slow open channel block in response to local and general anesthetic agents (15, 37).…”

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Modulation of a voltage-gated Na⁺channel by sevoflurane involves multiple sites and distinct mechanisms

Barber

Carnevale

Klein

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Halogenated inhaled general anesthetic agents modulate voltagegated ion channels, but the underlying molecular mechanisms are not understood. Many general anesthetic agents regulate voltagegated Na + (Na V ) channels, including the commonly used drug sevoflurane. Here, we investigated the putative binding sites and molecular mechanisms of sevoflurane action on the bacterial Na V channel NaChBac by using a combination of molecular dynamics simulation, electrophysiology, and kinetic analysis. Structural modeling revealed multiple sevoflurane interaction sites possibly associated with NaChBac modulation. Electrophysiologically, sevoflurane favors activation and inactivation at low concentrations (0.2 mM), and additionally accelerates current decay at high concentrations (2 mM). Explaining these observations, kinetic modeling suggests concurrent destabilization of closed states and low-affinity open channel block. We propose that the multiple effects of sevoflurane on NaChBac result from simultaneous interactions at multiple sites with distinct affinities. This multiple-site, multiple-mode hypothesis offers a framework to study the structural basis of general anesthetic action.anesthesia | MD simulations | anesthetics | membrane proteins G eneral anesthetic agents have been in use for more than 160 y.However, we still understand relatively little about their mechanisms of action, which greatly limits our ability to design safer and more effective general anesthetic agents. Ion channels of the central nervous system are known to be key targets of general anesthetic agents, as their modulation can account for the endpoints and side effects of general anesthesia (1-4). Many families of ion channels are modulated by general anesthetic agents, including ligand-gated, voltage-gated, and nongated ion channels (2, 5-7). Mammalian voltage-gated Na + (Na V ) channels, which mediate the upstroke of the action potential, are regulated by numerous inhaled general anesthetic agents (8-14), which generally cause inhibition. Previous work showed that inhaled general anesthetic agents, including sevoflurane, isoflurane, desflurane, and halothane, mediate inhibition by increasing the rate of Na + channel inactivation, hyperpolarizing steady-state inactivation, and slowing recovery from inactivation (11,(15)(16)(17)(18). Inhibition of presynaptic Na V channels in the spinal cord is proposed to lead to inhibition of neurotransmitter release, facilitating immobilization-one of the endpoints of general anesthesia (14,19,20). Despite the importance of Na V channels as general anesthetic targets, little is known about interaction sites or the mechanisms of action.What is known about anesthetic sites in Na V channels comes primarily from the local anesthetic field. Local anesthetic agent binding to Na V channels is well characterized. These amphiphilic drugs enter the channel pore from the intracellular side, causing open-channel block (21). Investigating molecular mechanisms of mammalian Na V channel modulation by general anesthetic agents...

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Structural and Functional Analysis of Sodium Channels Viewed from an Evolutionary Perspective

El-Din

Lenaeus

Catterall

2017

Handbook of Experimental Pharmacology

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Voltage-gated sodium channels initiate and propagate action potentials in excitable cells. They respond to membrane depolarization through opening, followed by fast inactivation that terminates the sodium current. This ON-OFF behavior of voltage-gated sodium channels underlays the coding of information and its transmission from one location in the nervous system to another. In this review, we explore and compare structural and functional data from prokaryotic and eukaryotic channels to infer the effects of evolution on sodium channel structure and function.

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The Pore, not Cytoplasmic Domains, Underlies Inactivation in a Prokaryotic Sodium Channel

Cited by 88 publications

References 40 publications

Comparative Study of the Gating Motif and C-type Inactivation in Prokaryotic Voltage-gated Sodium Channels

Comparative Study of the Gating Motif and C-type Inactivation in Prokaryotic Voltage-gated Sodium Channels

Modulation of a voltage-gated Na⁺channel by sevoflurane involves multiple sites and distinct mechanisms

Structural and Functional Analysis of Sodium Channels Viewed from an Evolutionary Perspective

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The Pore, not Cytoplasmic Domains, Underlies Inactivation in a Prokaryotic Sodium Channel

Cited by 88 publications

References 40 publications

Comparative Study of the Gating Motif and C-type Inactivation in Prokaryotic Voltage-gated Sodium Channels

Comparative Study of the Gating Motif and C-type Inactivation in Prokaryotic Voltage-gated Sodium Channels

Modulation of a voltage-gated Na+channel by sevoflurane involves multiple sites and distinct mechanisms

Structural and Functional Analysis of Sodium Channels Viewed from an Evolutionary Perspective

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Modulation of a voltage-gated Na⁺channel by sevoflurane involves multiple sites and distinct mechanisms