Your search keyword '"Scheuer T"' showing total 15 results

1. Enhancement of inhibitory neurotransmission by GABAA receptors having α2,3-subunits ameliorates behavioral deficits in a mouse model of autism.

Author

Han S, Tai C, Jones CJ, Scheuer T, and Catterall WA

Subjects

Animals, Autistic Disorder drug therapy, Benzodiazepines pharmacology, Brain metabolism, Disease Models, Animal, Fluorobenzenes pharmacology, Male, Mice, Mice, 129 Strain, Mice, Inbred C57BL, Protein Subunits metabolism, Pyridines pharmacology, Triazoles pharmacology, Zolpidem, Behavior, Animal drug effects, Brain drug effects, Interpersonal Relations, Receptors, GABA-A metabolism, Social Behavior, Synaptic Transmission drug effects

Abstract

Autism spectrum disorder (ASD) may arise from increased ratio of excitatory to inhibitory neurotransmission in the brain. Many pharmacological treatments have been tested in ASD, but only limited success has been achieved. Here we report that BTBR T(+)Itpr3(tf)/J (BTBR) mice, a model of idiopathic autism, have reduced spontaneous GABAergic neurotransmission. Treatment with low nonsedating/nonanxiolytic doses of benzodiazepines, which increase inhibitory neurotransmission through positive allosteric modulation of postsynaptic GABAA receptors, improved deficits in social interaction, repetitive behavior, and spatial learning. Moreover, negative allosteric modulation of GABAA receptors impaired social behavior in C57BL/6J and 129SvJ wild-type mice, suggesting that reduced inhibitory neurotransmission may contribute to social and cognitive deficits. The dramatic behavioral improvement after low-dose benzodiazepine treatment was subunit specific-the α2,3-subunit-selective positive allosteric modulator L-838,417 was effective, but the α1-subunit-selective drug zolpidem exacerbated social deficits. Impaired GABAergic neurotransmission may contribute to ASD, and α2,3-subunit-selective positive GABAA receptor modulation may be an effective treatment., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

2. Regulation of presynaptic Ca(V)2.1 channels by Ca2+ sensor proteins mediates short-term synaptic plasticity.

Author

Mochida S, Few AP, Scheuer T, and Catterall WA

Subjects

Amino Acid Motifs physiology, Animals, Calcium metabolism, Calcium Channel Blockers pharmacology, Cells, Cultured, Dose-Response Relationship, Radiation, Electric Stimulation, Excitatory Postsynaptic Potentials drug effects, Excitatory Postsynaptic Potentials physiology, Excitatory Postsynaptic Potentials radiation effects, Mice, Microinjections methods, Mutation, Neuronal Plasticity drug effects, Patch-Clamp Techniques methods, Superior Cervical Ganglion cytology, Time Factors, omega-Agatoxin IVA pharmacology, Calcium Channels, N-Type physiology, Intracellular Calcium-Sensing Proteins physiology, Neuronal Plasticity physiology, Neurons cytology, Presynaptic Terminals physiology

Abstract

Short-term synaptic plasticity shapes the postsynaptic response to bursts of impulses and is crucial for encoding information in neurons, but the molecular mechanisms are unknown. Here we show that activity-dependent modulation of presynaptic Ca(V)2.1 channels mediated by neuronal Ca(2+) sensor proteins (CaS) induces synaptic plasticity in cultured superior cervical ganglion (SCG) neurons. A mutation of the IQ-like motif in the C terminus that blocks Ca(2+)/CaS-dependent facilitation of the P/Q-type Ca(2+) current markedly reduces facilitation of synaptic transmission. Deletion of the nearby calmodulin-binding domain, which inhibits CaS-dependent inactivation, substantially reduces depression of synaptic transmission. These results demonstrate that residual Ca(2+) in presynaptic terminals can act through CaS-dependent regulation of Ca(V)2.1 channels to induce short-term synaptic facilitation and rapid synaptic depression. Activity-dependent regulation of presynaptic Ca(V)2.1 channels by CaS proteins may therefore be a primary determinant of short-term synaptic plasticity and information-processing in the nervous system.

Published

2008

3. Neuromodulation of Na+ channel slow inactivation via cAMP-dependent protein kinase and protein kinase C.

Author

Chen Y, Yu FH, Surmeier DJ, Scheuer T, and Catterall WA

Subjects

Amino Acid Sequence, Asparagine genetics, Aspartic Acid genetics, Cell Line, Cyclic AMP-Dependent Protein Kinase Type II, Diglycerides pharmacology, Dose-Response Relationship, Radiation, Electric Stimulation methods, Enzyme Inhibitors pharmacology, Humans, Ion Channel Gating drug effects, Ion Channel Gating physiology, Membrane Potentials drug effects, Membrane Potentials physiology, Membrane Potentials radiation effects, Models, Biological, Molecular Biology methods, Mutagenesis physiology, NAV1.2 Voltage-Gated Sodium Channel, Nucleotides, Cyclic pharmacology, Patch-Clamp Techniques methods, Protein Structure, Tertiary genetics, Reaction Time physiology, Reaction Time radiation effects, Transfection methods, Cyclic AMP-Dependent Protein Kinases physiology, Nerve Tissue Proteins physiology, Protein Kinase C physiology, Sodium Channels physiology

Abstract

Neurotransmitters modulate sodium channel availability through activation of G protein-coupled receptors, cAMP-dependent protein kinase (PKA), and protein kinase C (PKC). Voltage-dependent slow inactivation also controls sodium channel availability, synaptic integration, and neuronal firing. Here we show by analysis of sodium channel mutants that neuromodulation via PKA and PKC enhances intrinsic slow inactivation of sodium channels, making them unavailable for activation. Mutations in the S6 segment in domain III (N1466A,D) either enhance or block slow inactivation, implicating S6 segments in the molecular pathway for slow inactivation. Modulation of N1466A channels by PKC or PKA is increased, whereas modulation of N1466D is nearly completely blocked. These results demonstrate that neuromodulation by PKA and PKC is caused by their enhancement of intrinsic slow inactivation gating. Modulation of slow inactivation by neurotransmitters acting through G protein-coupled receptors, PKA, and PKC is a flexible mechanism of cellular plasticity controlling the firing behavior of central neurons.

Published

2006

4. Ion permeation through a voltage- sensitive gating pore in brain sodium channels having voltage sensor mutations.

Author

Sokolov S, Scheuer T, and Catterall WA

Subjects

Amino Acid Substitution, Animals, Arginine genetics, Electric Stimulation methods, Excitatory Amino Acids pharmacology, Ion Channel Gating drug effects, Ion Channel Gating genetics, Ion Channels drug effects, Ion Channels physiology, Membrane Potentials drug effects, Membrane Potentials physiology, Mutagenesis, Site-Directed physiology, N-Methylaspartate pharmacology, NAV1.2 Voltage-Gated Sodium Channel, Nerve Tissue Proteins chemistry, Nerve Tissue Proteins genetics, Neural Conduction drug effects, Neural Conduction genetics, Neural Conduction radiation effects, Oocytes, Patch-Clamp Techniques methods, Potassium Channel Blockers pharmacology, Sodium Channel Blockers pharmacology, Sodium Channels chemistry, Sodium Channels drug effects, Sodium Channels genetics, Sodium Channels metabolism, Tetraethylammonium pharmacology, Tetrodotoxin pharmacology, Transfection methods, Xenopus, Ion Channel Gating physiology, Mutation, Nerve Tissue Proteins metabolism, Sodium Channels physiology

Abstract

Voltage-gated sodium channels activate in response to depolarization, but it is unknown whether the voltage-sensing arginines in their S4 segments pivot across the lipid bilayer as voltage sensor paddles or move through the protein in a gating pore. Here we report that mutation of pairs of arginine gating charges to glutamine induces cation permeation through a gating pore in domain II of the Na(V)1.2a channel. Mutation of R850 and R853 induces a K(+)-selective inward cationic current in the resting state that is blocked by activation. Remarkably, mutation of R853 and R856 causes an outward cationic current with the opposite gating polarity. These results support a model in which the IIS4 gating charges move through a narrow constriction in a gating pore in the sodium channel protein during gating. Paired substitutions of glutamine allow cation movement through the constriction when appropriately positioned by the gating movements of the S4 segment.

Published

2005

5. A gating hinge in Na+ channels; a molecular switch for electrical signaling.

Author

Zhao Y, Yarov-Yarovoy V, Scheuer T, and Catterall WA

Subjects

Bacillus, Cell Membrane drug effects, Cells, Cultured, Evolution, Molecular, Glycine metabolism, Humans, Ion Channel Gating genetics, Membrane Potentials genetics, Models, Molecular, Mutation genetics, Patch-Clamp Techniques, Proline metabolism, Protein Structure, Secondary genetics, Bacterial Proteins genetics, Bacterial Proteins metabolism, Cell Membrane metabolism, Ion Channel Gating physiology, Sodium Channels genetics, Sodium Channels metabolism

Abstract

Voltage-gated sodium channels are members of a large family with similar pore structures. The mechanism of opening and closing is unknown, but structural studies suggest gating via bending of the inner pore helix at a glycine hinge. Here we provide functional evidence for this gating model for the bacterial sodium channel NaChBac. Mutation of glycine 219 to proline, which would strongly favor bending of the alpha helix, greatly enhances activation by shifting its voltage dependence -51 mV and slowing deactivation by 2000-fold. The mutation also slows voltage-dependent inactivation by 1200-fold. The effects are specific because substitutions of proline at neighboring positions and substitutions of other amino acids at position 219 have much smaller functional effects. Our results fit a model in which concerted bending at glycine 219 in the S6 segments of NaChBac serves as a gating hinge. This gating motion may be conserved in most members of this large ion channel protein family.

Published

2004

6. Transmitter modulation of slow, activity-dependent alterations in sodium channel availability endows neurons with a novel form of cellular plasticity.

Author

Carr DB, Day M, Cantrell AR, Held J, Scheuer T, Catterall WA, and Surmeier DJ

Subjects

Animals, Brain physiology, GTP-Binding Proteins metabolism, Membrane Potentials physiology, Mice, Models, Neurological, Organ Culture Techniques, Patch-Clamp Techniques, Phosphorylation, Protein Kinases metabolism, Receptors, Serotonin metabolism, Ion Channel Gating physiology, Neuronal Plasticity physiology, Neurons physiology, Sodium Channels physiology

Abstract

Voltage-gated Na+ channels are major targets of G protein-coupled receptor (GPCR)-initiated signaling cascades. These cascades act principally through protein kinase-mediated phosphorylation of the channel alpha subunit. Phosphorylation reduces Na+ channel availability in most instances without producing major alterations of fast channel gating. The nature of this change in availability is poorly understood. The results described here show that both GPCR- and protein kinase-dependent reductions in Na+ channel availability are mediated by a slow, voltage-dependent process with striking similarity to slow inactivation, an intrinsic gating mechanism of Na+ channels. This process is strictly associated with neuronal activity and develops over seconds, endowing neurons with a novel form of cellular plasticity shaping synaptic integration, dendritic electrogenesis, and repetitive discharge.

Published

2003

7. Voltage sensor-trapping: enhanced activation of sodium channels by beta-scorpion toxin bound to the S3-S4 loop in domain II.

Author

Cestèle S, Qu Y, Rogers JC, Rochat H, Scheuer T, and Catterall WA

Subjects

Amino Acid Sequence, Brain metabolism, Cell Line, Chimera physiology, Ion Channel Gating physiology, Mutation physiology, Myocardium metabolism, Scorpion Venoms pharmacology, Sodium Channels drug effects, Scorpion Venoms metabolism, Sodium Channels genetics, Sodium Channels metabolism

Abstract

Polypeptide neurotoxins alter ion channel gating by binding to extracellular receptor sites, even though the voltage sensors are in their S4 transmembrane segments. By analysis of sodium channel chimeras, a beta-scorpion toxin is shown here to negatively shift voltage dependence of activation and enhance closed state inactivation by binding to a receptor site that requires glycine 845 (Gly-845) in the S3-S4 loop at the extracellular end of the S4 segment in domain II of the alpha subunit. Toxin action requires prior depolarization to drive the S4 voltage sensors outward, but these effects are lost in the mutant G845N. The results reveal a voltage sensor-trapping model of toxin action in which the IIS4 voltage sensor is trapped in its outward, activated position by toxin binding.

Published

1998

8. Primary structure and function of an A kinase anchoring protein associated with calcium channels.

Author

Gray PC, Johnson BD, Westenbroek RE, Hays LG, Yates JR 3rd, Scheuer T, Catterall WA, and Murphy BJ

Subjects

A Kinase Anchor Proteins, Acetylation, Amino Acid Sequence, Animals, Blotting, Northern, Calcium Channels analysis, Calcium Channels, L-Type, Carrier Proteins analysis, Carrier Proteins metabolism, Cell Line, Consensus Sequence, Cyclic AMP-Dependent Protein Kinases genetics, Gene Expression Regulation, Enzymologic physiology, Humans, Ion Channel Gating physiology, Kidney cytology, Membrane Proteins analysis, Membrane Proteins metabolism, Microsomes chemistry, Microsomes enzymology, Molecular Sequence Data, Muscle Contraction physiology, Muscle Proteins analysis, Muscle Proteins metabolism, Muscle, Skeletal enzymology, Mutagenesis physiology, Precipitin Tests, Protein Binding physiology, RNA, Messenger analysis, Rabbits, Rats, Adaptor Proteins, Signal Transducing, Calcium Channels metabolism, Carrier Proteins genetics, Cyclic AMP-Dependent Protein Kinases metabolism, Membrane Proteins genetics, Muscle, Skeletal chemistry

Abstract

Rapid, voltage-dependent potentiation of skeletal muscle L-type calcium channels requires phosphorylation by cAMP-dependent protein kinase (PKA) anchored via an A kinase anchoring protein (AKAP). Here we report the isolation, primary sequence determination, and functional characterization of AKAP15, a lipid-anchored protein of 81 amino acid residues with a single amphipathic helix that binds PKA. AKAP15 colocalizes with L-type calcium channels in transverse tubules and is associated with L-type calcium channels in transfected cells. A peptide fragment of AKAP15 encompassing the RII-binding domain blocks voltage-dependent potentiation. These results indicate that AKAP15 targets PKA to the calcium channel and plays a critical role in voltage-dependent potentiation and regulation of skeletal muscle contraction. The expression of AKAP15 in the brain and heart suggests that it may mediate rapid PKA regulation of L-type calcium channels in neurons and cardiac myocytes.

Published

1998

9. Persistent sodium currents through brain sodium channels induced by G protein betagamma subunits.

Author

Ma JY, Catterall WA, and Scheuer T

Subjects

Animals, Humans, Patch-Clamp Techniques, Rats, Brain physiology, GTP-Binding Proteins physiology, Sodium Channels physiology

Abstract

Persistent Na+ currents are thought to be important for integration of neuronal responses. Here, we show that betagamma subunits of G proteins can induce persistent Na+ currents. Coexpression of G beta2gamma3, G beta1gamma3, or G beta5gamma3, but not G beta1gamma1 subunits with rat brain type IIA Na+ channel alpha subunits in tsA-201 cells greatly enhances a component of Na+ current with a normal voltage dependence of activation but with dramatically slowed and incomplete inactivation and with steady-state inactivation shifted +37 mV. Synthetic peptides containing the proposed G betagamma-binding motif, Gln-X-X-Glu-Arg, from either adenylyl cyclase 2 or the Na+ channel alpha subunit C-terminal domain reversed the effect of G beta2gamma3 subunits. These results are consistent with direct binding of G betagamma subunits to the C-terminal domain of the Na+ channel, stabilizing a gating mode responsible for slowed and persistent Na+ current. Modulation of Na+ channel gating by G betagamma subunits is expected to have profound effects on neuronal excitability.

Published

1997

10. Muscarinic modulation of sodium current by activation of protein kinase C in rat hippocampal neurons.

Author

Cantrell AR, Ma JY, Scheuer T, and Catterall WA

Subjects

Animals, Carbachol pharmacology, Enzyme Activation, Male, Phosphorylation, Rats, Sodium physiology, Hippocampus physiology, Ion Channel Gating, Protein Kinase C physiology, Receptors, Muscarinic physiology, Sodium Channels physiology

Abstract

Phosphorylation of brain Na+ channels by protein kinase C (PKC) decreases peak Na+ current and slows macroscopic inactivation, but receptor-activated modulation of Na+ currents via the PKC pathway has not been demonstrated. We have examined modulation of Na+ channels by activation of muscarinic receptors in acutely-isolated hippocampal neurons using whole-cell voltage-clamp recording. Application of the muscarinic agonist carbachol reduced peak Na+ current and slowed macroscopic inactivation at all potentials, without changing the voltage-dependent properties of the channel. These effects were mediated by PKC, since they were eliminated when the specific PKC inhibitor (PKCI19-36) was included in the pipette solution and mimicked by the extracellular application of the PKC activator, OAG. Thus, activation of endogenous muscarinic receptors on hippocampal neurons strongly modulates Na+ channel activity by activation of PKC. Cholinergic input from basal forebrain neurons may have this effect in the hippocampus in vivo.

Published

1996

11. Structure and function of the beta 2 subunit of brain sodium channels, a transmembrane glycoprotein with a CAM motif.

Author

Isom LL, Ragsdale DS, De Jongh KS, Westenbroek RE, Reber BF, Scheuer T, and Catterall WA

Subjects

Amino Acid Sequence, Animals, Brain embryology, Cell Membrane physiology, Cloning, Molecular, Contactins, DNA, Complementary genetics, Gene Expression physiology, Immunoglobulins genetics, Membrane Glycoproteins physiology, Molecular Sequence Data, Nerve Tissue Proteins genetics, Oocytes physiology, Rats, Sodium Channels ultrastructure, Spinal Cord chemistry, Spinal Cord embryology, Xenopus, Brain Chemistry physiology, Cell Adhesion Molecules physiology, Cell Adhesion Molecules, Neuronal, Sodium Channels physiology

Abstract

Voltage-gated sodium channels in brain neurons are complexes of a pore-forming alpha subunit with smaller beta 1 and beta 2 subunits. cDNA cloning and sequencing showed that the beta 2 subunit is a 186 residue glycoprotein with an extracellular NH2-terminal domain containing an immunoglobulin-like fold with similarity to the neural cell adhesion molecule (CAM) contactin, a single transmembrane segment, and a small intracellular domain. Coexpression of beta 2 with alpha subunits in Xenopus oocytes increases functional expression, modulates gating, and causes up to a 4-fold increase in the capacitance of the oocyte, which results from an increase in the surface area of the plasma membrane microvilli. beta 2 subunits are unique among the auxiliary subunits of ion channels in combining channel modulation with a CAM motif and the ability to expand the cell membrane surface area. They may be important regulators of sodium channel expression and localization in neurons.

Published

1995

12. Restoration of inactivation and block of open sodium channels by an inactivation gate peptide.

Author

Eaholtz G, Scheuer T, and Catterall WA

Subjects

Amino Acid Sequence, Animals, CHO Cells, Cell Line, Cricetinae, Humans, Ion Channel Gating drug effects, Ion Channel Gating physiology, Kidney, Kidney Neoplasms, Membrane Potentials drug effects, Molecular Sequence Data, Mutagenesis, Site-Directed, Oligopeptides chemical synthesis, Oligopeptides pharmacology, Peptides chemical synthesis, Rats, Sodium Channel Blockers, Sodium Channels biosynthesis, Transfection, Tumor Cells, Cultured, Peptides pharmacology, Sodium Channels physiology

Abstract

Inactivation of sodium channels terminates the sodium current responsible for initiation of action potentials in excitable cells. A hydrophobic sequence (isoleucine-phenylalanine-methionine, IFM), located in the inactivation gate segment connecting homologous domains III and IV of the sodium channel alpha subunit, is required for fast inactivation. A synthetic peptide containing the IFM sequence (acetyl-KIFMK-amide) restores fast inactivation to mutant sodium channels having a defective inactivation gate and to wild-type sodium channels having inactivation slowed by alpha-scorpion toxin. This peptide also competes with the intrinsic inactivation particle and binds to and blocks open sodium channels in a voltage- and frequency-dependent manner. A peptide (acetyl-KIQMK-amide) containing a mutation that prevents fast inactivation is not effective in restoring inactivation or in blocking open sodium channels. The results support the hypothesis that the sequence IFM serves as the inactivation particle of the sodium channel and suggest that it enters the intracellular mouth of the pore and occludes it during the process of inactivation.

Published

1994

13. Functional modulation of brain sodium channels by cAMP-dependent phosphorylation.

Author

Li M, West JW, Lai Y, Scheuer T, and Catterall WA

Subjects

Animals, Brain cytology, Cell Line, Neurons metabolism, Phosphorylation, Protein Kinases deficiency, Sodium Channels chemistry, Brain metabolism, Cyclic AMP metabolism, Sodium Channels metabolism

Abstract

Voltage-gated Na+ channels, which are responsible for the generation of action potentials in brain, are phosphorylated by cAMP-dependent protein kinase in vitro and in intact neurons. Phosphorylation by cAMP-dependent protein kinase reduces peak Na+ currents 40%--50% in membrane patches excised from rat brain neurons or from CHO cells expressing type IIA Na+ channels. Inhibition of basal cAMP-dependent protein kinase activity by transfection with a plasmid encoding a dominant negative mutant regulatory subunit increases Na+ channel number and activity, indicating that even the basal level of kinase activity is sufficient to reduce Na+ channel activity significantly. Na+ currents in membrane patches from kinase-deficient cells were reduced up to 80% by phosphorylation by cAMP-dependent protein kinase. These effects could be blocked by a specific peptide inhibitor of cAMP-dependent protein kinase and reversed by phosphoprotein phosphatases. Convergent modulation of brain Na+ channels by neurotransmitters acting through the cAMP and protein kinase C signaling pathways may result in associative regulation of electrical activity by different synaptic inputs.

Published

1992

14. Phosphorylation of a conserved protein kinase C site is required for modulation of Na+ currents in transfected Chinese hamster ovary cells.

Author

West JW, Numann R, Murphy BJ, Scheuer T, and Catterall WA

Subjects

Animals, Binding Sites, Biophysical Phenomena, Biophysics, CHO Cells, Cricetinae, Phosphorylation, Sodium Channels genetics, Transfection, Protein Kinase C metabolism, Sodium Channels metabolism

Published

1992

15. Efficient expression of rat brain type IIA Na+ channel alpha subunits in a somatic cell line.

Author

West JW, Scheuer T, Maechler L, and Catterall WA

Subjects

Animals, Base Sequence, Blotting, Northern, CHO Cells, Cell Nucleus physiology, Cricetinae, DNA chemistry, DNA genetics, Electric Conductivity, Macromolecular Substances, Microinjections, Molecular Sequence Data, Plasmids, RNA, Messenger genetics, RNA, Messenger metabolism, Rats, Receptors, Cholinergic metabolism, Saxitoxin metabolism, Saxitoxin pharmacology, Sodium Channels physiology, Tetrodotoxin metabolism, Tetrodotoxin pharmacology, Transfection, Brain Chemistry, Gene Expression, Sodium Channels genetics

Abstract

Type IIA rat brain Na+ channel alpha subunits were expressed in CHO cells by nuclear microinjection or by transfection using a vector containing both metallothionein and bacteriophage SP6 promoters. Stable cell lines expressing Na+ channels were isolated, and whole-cell Na+ currents of 0.9-14 nA were recorded. The mean level of whole-cell Na+ current (4.5 nA) corresponds to a cell surface density of approximately 2 channels active at the peak of the Na+ current per microns 2, a density comparable to that observed in the cell bodies of central neurons. The expressed Na+ channels had the voltage dependence, rapid activation and inactivation, and rapid recovery from inactivation characteristic of Na+ channels in brain neurons, bound toxins at neurotoxin receptor sites 1 and 3 with normal properties, and were posttranslationally processed to a normal mature size of 260 kd. Expression of Na+ channel cDNA in CHO cells driven by the metallothionein promoter accurately and efficiently reproduces native Na+ channel properties and provides a method for combined biochemical and physiological analysis of Na+ channel structure and function.

Published

1992