Neuroactive steroids are potent modulators of ␥-aminobutyric acid type A receptors (GABA ARs), and their behavioral effects are generally viewed in terms of altered inhibitory synaptic transmission. Here we report that, at concentrations known to occur in vivo, neuroactive steroids specifically enhance a tonic inhibitory conductance in central neurons that is mediated by extrasynaptic ␦ subunit-containing GABAARs. The neurosteroid-induced augmentation of this tonic conductance decreases neuronal excitability. Fluctuations in the circulating concentrations of endogenous neuroactive steroids have been implicated in the genesis of premenstrual syndrome, postpartum depression, and other anxiety disorders. Recognition that ␦ subunit-containing GABAARs responsible for a tonic conductance are a preferential target for neuroactive steroids may lead to novel pharmacological approaches for the treatment of these common conditions. hippocampus ͉ cerebellum ͉ neurosteroids ͉ inhibitory postsynaptic currents ͉ ␦ knockout mice G ABA A Rs (␥-aminobutyric acid type A receptors) are pentameric proteins that form Cl Ϫ -permeable ion channels activated by the neurotransmitter GABA. To date, 19 mammalian GABA A subunit isoforms have been identified, and these assemble to produce the dozen or so different receptor subtypes most frequently found in the brain (1). The most potent positive endogenous modulators of GABA A R function are the 3␣-hydroxy ring A-reduced pregnane steroids, that have sedativehypnotic, anticonvulsant, and anxiolytic effects (2-4). Severe mood disorders that can occur during the menstrual cycle and after pregnancy are suggested to involve alterations in the function of synaptic GABA A Rs (2, 3, 5) triggered by rapid decreases in the concentrations of these progesterone-derived neuroactive steroids (6).Recently, it has become apparent that distinct GABA A Rs participate in two types of inhibitory control. Transient activation of synaptic GABA A Rs is responsible for conventional phasic inhibition, whereas the continuous activation of extrasynaptic GABA A Rs can generate a form of tonic inhibition (7-14). GABA A Rs containing the ␦ subunit are restricted to extrasynaptic locations (15) and have an unusually high affinity for GABA (16,17), making them likely mediators of the tonic GABA A conductance recorded in both cerebellar (7,8) and dentate gyrus granule cells (DGGC) (10, 11). In mice lacking the ␦ subunit of the GABA A R, the effects of neuroactive steroids are greatly reduced (18). Moreover, recent reports (17,19,20) have raised the possibility that the steroid sensitivity of ␦ subunitcontaining GABA A Rs may be much higher than previously thought (21). In light of these findings, and the possible involvement of ␦ subunit-containing receptors in generating tonic conductances (8-11), we recorded from wild-type and ␦Ϫ͞Ϫ mice, and examined the effects of the naturally occurring neuroactive steroid 3␣,21-dihydroxy-5␣-pregnan-20-one (allotetrahydrodeoxycorticosterone, THDOC) on the tonic GABA A R-mediated conduct...
Extracellular Mg2+ directly modulates voltage-dependent activation in ether-à-go-go (eag) potassium channels, slowing the kinetics of ionic and gating currents (Tang, C.-Y., F. Bezanilla, and D.M. Papazian. 2000. J. Gen. Physiol. 115:319-337). To exert its effect, Mg2+ presumably binds to a site in or near the eag voltage sensor. We have tested the hypothesis that acidic residues unique to eag family members, located in transmembrane segments S2 and S3, contribute to the Mg2+-binding site. Two eag-specific acidic residues and three acidic residues found in the S2 and S3 segments of all voltage-dependent K+ channels were individually mutated in Drosophila eag, mutant channels were expressed in Xenopus oocytes, and the effect of Mg2+ on ionic current kinetics was measured using a two electrode voltage clamp. Neutralization of eag-specific residues D278 in S2 and D327 in S3 eliminated Mg2+-sensitivity and mimicked the slowing of activation kinetics caused by Mg2+ binding to the wild-type channel. These results suggest that Mg2+ modulates activation kinetics in wild-type eag by screening the negatively charged side chains of D278 and D327. Therefore, these residues are likely to coordinate the bound ion. In contrast, neutralization of the widely conserved residues D284 in S2 and D319 in S3 preserved the fast kinetics seen in wild-type eag in the absence of Mg2+, indicating that D284 and D319 do not mediate the slowing of activation caused by Mg2+ binding. Mutations at D284 affected the eag gating pathway, shifting the voltage dependence of Mg2+-sensitive, rate limiting transitions in the hyperpolarized direction. Another widely conserved residue, D274 in S2, is not required for Mg2+ sensitivity but is in the vicinity of the binding site. We conclude that Mg2+ binds in a water-filled pocket between S2 and S3 and thereby modulates voltage-dependent gating. The identification of this site constrains the packing of transmembrane segments in the voltage sensor of K+ channels, and suggests a molecular mechanism by which extracellular cations modulate eag activation kinetics.
We have characterized the effects of prepulse hyperpolarization and extracellular Mg2+ on the ionic and gating currents of the Drosophila ether-à-go-go K+ channel (eag). Hyperpolarizing prepulses significantly slowed channel opening elicited by a subsequent depolarization, revealing rate-limiting transitions for activation of the ionic currents. Extracellular Mg2+ dramatically slowed activation of eag ionic currents evoked with or without prepulse hyperpolarization and regulated the kinetics of channel opening from a nearby closed state(s). These results suggest that Mg2+ modulates voltage-dependent gating and pore opening in eag channels. To investigate the mechanism of this modulation, eag gating currents were recorded using the cut-open oocyte voltage clamp. Prepulse hyperpolarization and extracellular Mg2+ slowed the time course of ON gating currents. These kinetic changes resembled the results at the ionic current level, but were much smaller in magnitude, suggesting that prepulse hyperpolarization and Mg2+ modulate gating transitions that occur slowly and/or move relatively little gating charge. To determine whether quantitatively different effects on ionic and gating currents could be obtained from a sequential activation pathway, computer simulations were performed. Simulations using a sequential model for activation reproduced the key features of eag ionic and gating currents and their modulation by prepulse hyperpolarization and extracellular Mg2+. We have also identified mutations in the S3–S4 loop that modify or eliminate the regulation of eag gating by prepulse hyperpolarization and Mg2+, indicating an important role for this region in the voltage-dependent activation of eag.
Many voltage-activated K+ channels contain two conserved cysteine residues in putative transmembrane segments S2 and S6. It has been proposed that these cysteines form an intrasubunit disulfide bond [Guy, H.R., & Conti, F. (1990) Trends Neurosci. 13, 201-206]. This proposal was tested using site-directed mutagenesis followed by electrophysiological and biochemical analysis of the Shaker B K+ channel. Each Shaker B subunit contains seven cysteine residues, including the conserved residues C286 and C462 and a less conserved cysteine, C245. Each cysteine in the Shaker B protein can be mutated individually without eliminating functional activity, indicating that the protein does not contain a disulfide bond that is essential for protein folding or the assembly of active channels. To determine whether there is a nonessential disulfide bond, Shaker B protein was subjected to limited proteolysis. Fragments were analyzed by electrophoresis under reducing and nonreducing conditions followed by immunoblotting. The results indicate that the two conserved residues C286 and C462 do not form a disulfide bond with each other or with C245. In addition, the subunits are not linked by disulfide bonds. In HEK293T cells, Shaker B protein is first made as an incompletely glycosylated precursor that is converted to the fully glycosylated mature protein. Glycosylation occurs at two positions in the S1-S2 loop.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
