Your search keyword '"Nerbonne JM"' showing total 17 results

1. Effects of NALCN-Encoded Na + Leak Currents on the Repetitive Firing Properties of SCN Neurons Depend on K + -Driven Rhythmic Changes in Input Resistance.

Author

Yang ND, Mellor RL, Hermanstyne TO, and Nerbonne JM

Subjects

Mice, Male, Female, Animals, Membrane Potentials physiology, Action Potentials physiology, Circadian Rhythm physiology, Neurons physiology, Suprachiasmatic Nucleus physiology, Mammals, Ion Channels, Membrane Proteins, Suprachiasmatic Nucleus Neurons

Abstract

Neurons in the suprachiasmatic nucleus (SCN) generate circadian changes in the rates of spontaneous action potential firing that regulate and synchronize daily rhythms in physiology and behavior. Considerable evidence suggests that daily rhythms in the repetitive firing rates (higher during the day than at night) of SCN neurons are mediated by changes in subthreshold potassium (K + ) conductance(s). An alternative "bicycle" model for circadian regulation of membrane excitability in clock neurons, however, suggests that an increase in NALCN-encoded sodium (Na + ) leak conductance underlies daytime increases in firing rates. The experiments reported here explored the role of Na + leak currents in regulating daytime and nighttime repetitive firing rates in identified adult male and female mouse SCN neurons: vasoactive intestinal peptide-expressing (VIP + ), neuromedin S-expressing (NMS + ) and gastrin-releasing peptide-expressing (GRP + ) cells. Whole-cell recordings from VIP + , NMS + , and GRP + neurons in acute SCN slices revealed that Na + leak current amplitudes/densities are similar during the day and at night, but have a larger impact on membrane potentials in daytime neurons. Additional experiments, using an in vivo conditional knockout approach, demonstrated that NALCN-encoded Na + currents selectively regulate daytime repetitive firing rates of adult SCN neurons. Dynamic clamp-mediated manipulation revealed that the effects of NALCN-encoded Na + currents on the repetitive firing rates of SCN neurons depend on K + current-driven changes in input resistances. Together, these findings demonstrate that NALCN-encoded Na + leak channels contribute to regulating daily rhythms in the excitability of SCN neurons by a mechanism that depends on K + current-mediated rhythmic changes in intrinsic membrane properties. SIGNIFICANCE STATEMENT Elucidating the ionic mechanisms responsible for generating daily rhythms in the rates of spontaneous action potential firing of neurons in the suprachiasmatic nucleus (SCN), the master circadian pacemaker in mammals, is an important step toward understanding how the molecular clock controls circadian rhythms in physiology and behavior. While numerous studies have focused on identifying subthreshold K + channel(s) that mediate day-night changes in the firing rates of SCN neurons, a role for Na + leak currents has also been suggested. The results of the experiments presented here demonstrate that NALCN-encoded Na + leak currents differentially modulate daily rhythms in the daytime/nighttime repetitive firing rates of SCN neurons as a consequence of rhythmic changes in subthreshold K + currents., (Copyright © 2023 the authors.)

Published

2023

2. Intracellular FGF14 (iFGF14) Is Required for Spontaneous and Evoked Firing in Cerebellar Purkinje Neurons and for Motor Coordination and Balance.

Author

Bosch MK, Carrasquillo Y, Ransdell JL, Kanakamedala A, Ornitz DM, and Nerbonne JM

Subjects

Action Potentials physiology, Animals, Ankyrins metabolism, Axons metabolism, Cell Line, Transformed, Cricetulus, Female, Fibroblast Growth Factors genetics, Gene Expression Regulation genetics, In Vitro Techniques, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, MicroRNAs genetics, MicroRNAs metabolism, NAV1.1 Voltage-Gated Sodium Channel metabolism, Purkinje Cells cytology, Action Potentials genetics, Cerebellum cytology, Fibroblast Growth Factors metabolism, Postural Balance genetics, Psychomotor Performance physiology, Purkinje Cells physiology

Abstract

Mutations in FGF14, which encodes intracellular fibroblast growth factor 14 (iFGF14), have been linked to spinocerebellar ataxia (SCA27). In addition, mice lacking Fgf14 (Fgf14(-/-)) exhibit an ataxia phenotype resembling SCA27, accompanied by marked changes in the excitability of cerebellar granule and Purkinje neurons. It is not known, however, whether these phenotypes result from defects in neuronal development or if they reflect a physiological requirement for iFGF14 in the adult cerebellum. Here, we demonstrate that the acute and selective Fgf14-targeted short hairpin RNA (shRNA)-mediated in vivo "knock-down" of iFGF14 in adult Purkinje neurons attenuates spontaneous and evoked action potential firing without measurably affecting the expression or localization of voltage-gated Na(+) (Nav) channels at Purkinje neuron axon initial segments. The selective shRNA-mediated in vivo "knock-down" of iFGF14 in adult Purkinje neurons also impairs motor coordination and balance. Repetitive firing can be restored in Fgf14-targeted shRNA-expressing Purkinje neurons, as well as in Fgf14(-/-) Purkinje neurons, by prior membrane hyperpolarization, suggesting that the iFGF14-mediated regulation of the excitability of mature Purkinje neurons depends on membrane potential. Further experiments revealed that the loss of iFGF14 results in a marked hyperpolarizing shift in the voltage dependence of steady-state inactivation of the Nav currents in adult Purkinje neurons. We also show here that expressing iFGF14 selectively in adult Fgf14(-/-) Purkinje neurons rescues spontaneous firing and improves motor performance. Together, these results demonstrate that iFGF14 is required for spontaneous and evoked action potential firing in adult Purkinje neurons, thereby controlling the output of these cells and the regulation of motor coordination and balance., (Copyright © 2015 the authors 0270-6474/15/356752-18$15.00/0.)

Published

2015

3. Distinct balance of excitation and inhibition in an interareal feedforward and feedback circuit of mouse visual cortex.

Author

Yang W, Carrasquillo Y, Hooks BM, Nerbonne JM, and Burkhalter A

Subjects

Animals, Excitatory Postsynaptic Potentials physiology, Female, Male, Mice, Mice, Inbred C57BL, Mice, Transgenic, Neural Pathways physiology, Organ Culture Techniques, Photic Stimulation methods, Feedback, Physiological physiology, Nerve Net physiology, Neural Inhibition physiology, Visual Cortex physiology, Visual Pathways physiology

Abstract

Mouse visual cortex is subdivided into multiple distinct, hierarchically organized areas that are interconnected through feedforward (FF) and feedback (FB) pathways. The principal synaptic targets of FF and FB axons that reciprocally interconnect primary visual cortex (V1) with the higher lateromedial extrastriate area (LM) are pyramidal cells (Pyr) and parvalbumin (PV)-expressing GABAergic interneurons. Recordings in slices of mouse visual cortex have shown that layer 2/3 Pyr cells receive excitatory monosynaptic FF and FB inputs, which are opposed by disynaptic inhibition. Most notably, inhibition is stronger in the FF than FB pathway, suggesting pathway-specific organization of feedforward inhibition (FFI). To explore the hypothesis that this difference is due to diverse pathway-specific strengths of the inputs to PV neurons we have performed subcellular Channelrhodopsin-2-assisted circuit mapping in slices of mouse visual cortex. Whole-cell patch-clamp recordings were obtained from retrobead-labeled FF(V1→LM)- and FB(LM→V1)-projecting Pyr cells, as well as from tdTomato-expressing PV neurons. The results show that the FF(V1→LM) pathway provides on average 3.7-fold stronger depolarizing input to layer 2/3 inhibitory PV neurons than to neighboring excitatory Pyr cells. In the FB(LM→V1) pathway, depolarizing inputs to layer 2/3 PV neurons and Pyr cells were balanced. Balanced inputs were also found in the FF(V1→LM) pathway to layer 5 PV neurons and Pyr cells, whereas FB(LM→V1) inputs to layer 5 were biased toward Pyr cells. The findings indicate that FFI in FF(V1→LM) and FB(LM→V1) circuits are organized in a pathway- and lamina-specific fashion.

Published

2013

4. I(A) channels encoded by Kv1.4 and Kv4.2 regulate neuronal firing in the suprachiasmatic nucleus and circadian rhythms in locomotor activity.

Author

Granados-Fuentes D, Norris AJ, Carrasquillo Y, Nerbonne JM, and Herzog ED

Subjects

Animals, Ion Channel Gating physiology, Kv1.4 Potassium Channel genetics, Male, Membrane Potentials physiology, Mice, Mice, Knockout, Shal Potassium Channels genetics, Action Potentials physiology, Circadian Rhythm physiology, Kv1.4 Potassium Channel metabolism, Motor Activity physiology, Neurons physiology, Shal Potassium Channels metabolism, Suprachiasmatic Nucleus physiology

Abstract

Neurons in the suprachiasmatic nucleus (SCN) display coordinated circadian changes in electrical activity that are critical for daily rhythms in physiology, metabolism, and behavior. SCN neurons depolarize spontaneously and fire repetitively during the day and hyperpolarize, drastically reducing firing rates, at night. To explore the hypothesis that rapidly activating and inactivating A-type (I(A)) voltage-gated K(+) (Kv) channels, which are also active at subthreshold membrane potentials, are critical regulators of the excitability of SCN neurons, we examined locomotor activity and SCN firing in mice lacking Kv1.4 (Kv1.4(-/-)), Kv4.2 (Kv4.2(-/-)), or Kv4.3 (Kv4.3(-/-)), the pore-forming (α) subunits of I(A) channels. Mice lacking either Kv1.4 or Kv4.2 α subunits have markedly shorter (0.5 h) periods of locomotor activity than wild-type (WT) mice. In vitro extracellular multi-electrode recordings revealed that Kv1.4(-/-) and Kv4.2(-/-) SCN neurons display circadian rhythms in repetitive firing, but with shorter periods (0.5 h) than WT cells. In contrast, the periods of wheel-running activity in Kv4.3(-/-) mice and firing in Kv4.3(-/-) SCN neurons were indistinguishable from WT animals and neurons. Quantitative real-time PCR revealed that the transcripts encoding all three Kv channel α subunits, Kv1.4, Kv4.2, and Kv4.3, are expressed constitutively throughout the day and night in the SCN. Together, these results demonstrate that Kv1.4- and Kv4.2-encoded I(A) channels regulate the intrinsic excitability of SCN neurons during the day and night and determine the period and amplitude of circadian rhythms in SCN neuron firing and locomotor behavior.

Published

2012

5. The sodium channel accessory subunit Navβ1 regulates neuronal excitability through modulation of repolarizing voltage-gated K⁺ channels.

Author

Marionneau C, Carrasquillo Y, Norris AJ, Townsend RR, Isom LL, Link AJ, and Nerbonne JM

Subjects

Analysis of Variance, Animals, Bacterial Proteins genetics, Bacterial Proteins metabolism, Biophysics, Biotinylation, Cell Line, Transformed, Cerebral Cortex cytology, Cycloheximide pharmacology, Electric Stimulation, Endocytosis drug effects, Endocytosis genetics, Gene Expression Regulation genetics, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Humans, Immunoprecipitation, Luminescent Proteins genetics, Luminescent Proteins metabolism, Mass Spectrometry, Mice, Mice, Inbred C57BL, Mice, Knockout, Neurons drug effects, Patch-Clamp Techniques, Protein Synthesis Inhibitors pharmacology, Proteomics, RNA, Small Interfering genetics, RNA, Small Interfering metabolism, Receptors, Transferrin metabolism, Shal Potassium Channels deficiency, Sodium Channels deficiency, Transfection, Voltage-Gated Sodium Channel beta-1 Subunit, Gene Expression Regulation physiology, Neurons physiology, Shal Potassium Channels metabolism, Sodium Channels metabolism

Abstract

The channel pore-forming α subunit Kv4.2 is a major constituent of A-type (I(A)) potassium currents and a key regulator of neuronal membrane excitability. Multiple mechanisms regulate the properties, subcellular targeting, and cell-surface expression of Kv4.2-encoded channels. In the present study, shotgun proteomic analyses of immunoprecipitated mouse brain Kv4.2 channel complexes unexpectedly identified the voltage-gated Na⁺ channel accessory subunit Navβ1. Voltage-clamp and current-clamp recordings revealed that knockdown of Navβ1 decreases I(A) densities in isolated cortical neurons and that action potential waveforms are prolonged and repetitive firing is increased in Scn1b-null cortical pyramidal neurons lacking Navβ1. Biochemical and voltage-clamp experiments further demonstrated that Navβ1 interacts with and increases the stability of the heterologously expressed Kv4.2 protein, resulting in greater total and cell-surface Kv4.2 protein expression and in larger Kv4.2-encoded current densities. Together, the results presented here identify Navβ1 as a component of native neuronal Kv4.2-encoded I(A) channel complexes and a novel regulator of I(A) channel densities and neuronal excitability.

Published

2012

6. Interdependent roles for accessory KChIP2, KChIP3, and KChIP4 subunits in the generation of Kv4-encoded IA channels in cortical pyramidal neurons.

Author

Norris AJ, Foeger NC, and Nerbonne JM

Subjects

Animals, Blotting, Western, Cells, Cultured, Electrophysiology, Immunoprecipitation, Ion Channel Gating physiology, Membrane Potentials physiology, Mice, Pyramidal Cells cytology, Reverse Transcriptase Polymerase Chain Reaction, Up-Regulation, Visual Cortex cytology, Kv Channel-Interacting Proteins physiology, Pyramidal Cells physiology, Repressor Proteins physiology, Visual Cortex physiology

Abstract

The rapidly activating and inactivating voltage-dependent outward K(+) (Kv) current, I(A), is widely expressed in central and peripheral neurons. I(A) has long been recognized to play important roles in determining neuronal firing properties and regulating neuronal excitability. Previous work demonstrated that Kv4.2 and Kv4.3 α-subunits are the primary determinants of I(A) in mouse cortical pyramidal neurons. Accumulating evidence indicates that native neuronal Kv4 channels function in macromolecular protein complexes that contain accessory subunits and other regulatory molecules. The K(+) channel interacting proteins (KChIPs) are among the identified Kv4 channel accessory subunits and are thought to be important for the formation and functioning of neuronal Kv4 channel complexes. Molecular genetic, biochemical, and electrophysiological approaches were exploited in the experiments described here to examine directly the roles of KChIPs in the generation of functional Kv4-encoded I(A) channels. These combined experiments revealed that KChIP2, KChIP3, and KChIP4 are robustly expressed in adult mouse posterior (visual) cortex and that all three proteins coimmunoprecipitate with Kv4.2. In addition, in cortical pyramidal neurons from mice lacking KChIP3 (KChIP3(-/-)), mean I(A) densities were reduced modestly, whereas in mean I(A) densities in KChIP2(-/-) and WT neurons were not significantly different. Interestingly, in both KChIP3(-/-) and KChIP2(-/-) cortices, the expression levels of the other KChIPs (KChIP2 and 4 or KChIP3 and 4, respectively) were increased. In neurons expressing constructs to mediate simultaneous RNA interference-induced reductions in the expression of KChIP2, 3, and 4, I(A) densities were markedly reduced and Kv current remodeling was evident.

Published

2010

7. Molecular dissection of I(A) in cortical pyramidal neurons reveals three distinct components encoded by Kv4.2, Kv4.3, and Kv1.4 alpha-subunits.

Author

Norris AJ and Nerbonne JM

Subjects

Action Potentials drug effects, Action Potentials genetics, Animals, Cerebral Cortex drug effects, Female, GTP-Binding Protein alpha Subunits, Gi-Go antagonists & inhibitors, GTP-Binding Protein alpha Subunits, Gi-Go deficiency, Gene Targeting, Kv1.4 Potassium Channel antagonists & inhibitors, Kv1.4 Potassium Channel deficiency, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Neurons drug effects, Neurons physiology, Potassium Channel Blockers pharmacology, Protein Subunits antagonists & inhibitors, Protein Subunits deficiency, Pyramidal Cells drug effects, Shal Potassium Channels antagonists & inhibitors, Shal Potassium Channels deficiency, Cerebral Cortex physiology, GTP-Binding Protein alpha Subunits, Gi-Go genetics, Ion Channel Gating genetics, Kv1.4 Potassium Channel genetics, Protein Subunits genetics, Pyramidal Cells physiology, Shal Potassium Channels genetics

Abstract

The rapidly activating and inactivating voltage-gated K(+) (Kv) current, I(A), is broadly expressed in neurons and is a key regulator of action potential repolarization, repetitive firing, backpropagation (into dendrites) of action potentials, and responses to synaptic inputs. Interestingly, results from previous studies on a number of neuronal cell types, including hippocampal, cortical, and spinal neurons, suggest that macroscopic I(A) is composed of multiple components and that each component is likely encoded by distinct Kv channel alpha-subunits. The goals of the experiments presented here were to test this hypothesis and to determine the molecular identities of the Kv channel alpha-subunits that generate I(A) in cortical pyramidal neurons. Combining genetic disruption of individual Kv alpha-subunit genes with pharmacological approaches to block Kv currents selectively, the experiments here revealed that Kv1.4, Kv4.2, and Kv4.3 alpha-subunits encode distinct components of I(A) that together underlie the macroscopic I(A) in mouse (male and female) cortical pyramidal neurons. Recordings from neurons lacking both Kv4.2 and Kv4.3 (Kv4.2(-/-)/Kv4.3(-/-)) revealed that, although Kv1.4 encodes a minor component of I(A), the Kv1.4-encoded current was found in all the Kv4.2(-/-)/Kv4.3(-/-) cortical pyramidal neurons examined. Of the cortical pyramidal neurons lacking both Kv4.2 and Kv1.4, 90% expressed a Kv4.3-encoded I(A) larger in amplitude than the Kv1.4-encoded component. The experimental findings also demonstrate that the targeted deletion of the individual Kv alpha-subunits encoding components of I(A) results in electrical remodeling that is Kv alpha-subunit specific.

Published

2010

8. The FGF14(F145S) mutation disrupts the interaction of FGF14 with voltage-gated Na+ channels and impairs neuronal excitability.

Author

Laezza F, Gerber BR, Lou JY, Kozel MA, Hartman H, Craig AM, Ornitz DM, and Nerbonne JM

Subjects

Animals, Cells, Cultured, Dose-Response Relationship, Radiation, Electric Stimulation methods, Embryo, Mammalian, Fibroblast Growth Factors genetics, Gene Expression Regulation genetics, Green Fluorescent Proteins biosynthesis, Hippocampus cytology, Humans, Immunoprecipitation methods, Ion Channel Gating physiology, Membrane Potentials drug effects, Membrane Potentials genetics, Membrane Potentials radiation effects, Neurons drug effects, Patch-Clamp Techniques methods, Rats, Sodium Channel Blockers pharmacology, Sodium Channels chemistry, Sodium Channels genetics, Tetrodotoxin pharmacology, Fibroblast Growth Factors physiology, Mutation physiology, Neurons physiology, Phenylalanine genetics, Serine genetics, Sodium Channels physiology

Abstract

Fibroblast growth factor 14 (FGF14) belongs to the intracellular FGF homologous factor subfamily of FGF proteins (iFGFs) that are not secreted and do not activate tyrosine kinase receptors. The iFGFs, however, have been shown to interact with the pore-forming (alpha) subunits of voltage-gated Na+ (Na(v)) channels. The neurological phenotypes seen in Fgf14-/- mice and the identification of an FGF14 missense mutation (FGF14(F145S)) in a Dutch family presenting with cognitive impairment and spinocerebellar ataxia suggest links between FGF14 and neuronal functioning. Here, we demonstrate that the expression of FGF14(F145S) reduces Na(v) alpha subunit expression at the axon initial segment, attenuates Na(v) channel currents, and reduces the excitability of hippocampal neurons. In addition, and in contrast with wild-type FGF14, FGF14(F145S) does not interact directly with Na(v) channel alpha subunits. Rather, FGF14(F145S) associates with wild-type FGF14 and disrupts the interaction between wild-type FGF14 and Na(v) alpha subunits, suggesting that the mutant FGF14(F145S) protein acts as a dominant negative, interfering with the interaction between wild-type FGF14 and Na(v) channel alpha subunits and altering neuronal excitability.

Published

2007

9. Differential expression of I(A) channel subunits Kv4.2 and Kv4.3 in mouse visual cortical neurons and synapses.

Author

Burkhalter A, Gonchar Y, Mellor RL, and Nerbonne JM

Subjects

Animals, Bacterial Proteins genetics, Immunohistochemistry methods, Luminescent Proteins genetics, Mice, Mice, Transgenic, Microscopy, Immunoelectron methods, Neurons ultrastructure, Shal Potassium Channels deficiency, Synapses ultrastructure, gamma-Aminobutyric Acid metabolism, Gene Expression physiology, Neurons metabolism, Shal Potassium Channels metabolism, Synapses metabolism, Visual Cortex cytology

Abstract

In cortical neurons, pore-forming alpha-subunits of the Kv4 subfamily underlie the fast transient outward K+ current (I(A)). Considerable evidence has accumulated demonstrating specific roles for I(A) channels in the generation of individual action potentials and in the regulation of repetitive firing. Although I(A) channels are thought to play a role in synaptic processing, little is known about the cell type- and synapse-specific distribution of these channels in cortical circuits. Here, we used immunolabeling with specific antibodies against Kv4.2 and Kv4.3, in combination with GABA immunogold staining, to determine the cellular, subcellular, and synaptic localization of Kv4 channels in the primary visual cortex of mice, in which subsets of pyramidal cells express yellow fluorescent protein. The results show that both Kv4.2 and Kv4.3 are concentrated in layer 1, the bottom of layer 2/3, and in layers 4 and 5/6. In all layers, clusters of Kv4.2 and Kv4.3 immunoreactivity are evident in the membranes of the somata, dendrites, and spines of pyramidal cells and GABAergic interneurons. Electron microscopic analyses revealed that Kv4.2 and Kv4.3 clusters in pyramidal cells and interneurons are excluded from putative excitatory synapses, whereas postsynaptic membranes at GABAergic synapses often contain Kv4.2 and Kv4.3. The presence of Kv4 channels at GABAergic synapses would be expected to weaken inhibition during dendritic depolarization by backpropagating action potentials. The extrasynaptic localization of Kv4 channels near excitatory synapses, in contrast, should stabilize synaptic excitation during dendritic depolarization. Thus, the synapse-specific distribution of Kv4 channels functions to optimize dendritic excitation and the association between presynaptic and postsynaptic activity.

Published

2006

10. Functional role of the fast transient outward K+ current IA in pyramidal neurons in (rat) primary visual cortex.

Author

Yuan W, Burkhalter A, and Nerbonne JM

Subjects

Action Potentials physiology, Animals, Animals, Newborn, Cells, Cultured, Complement Hemolytic Activity Assay methods, Electric Stimulation methods, Gene Expression Regulation physiology, Green Fluorescent Proteins biosynthesis, Immunohistochemistry methods, Macromolecular Substances, Membrane Potentials drug effects, Membrane Potentials physiology, Mutagenesis physiology, Protein Subunits physiology, Rats, Rats, Long-Evans, Transfection methods, Pyramidal Cells physiology, Visual Cortex cytology

Abstract

A molecular genetic approach was exploited to directly test the hypothesis that voltage-gated K+ (Kv) channel pore-forming (alpha) subunits of the Kv4 subfamily encode the fast transient outward K+ current (IA) in cortical pyramidal neurons and to explore the functional role of IA in shaping action potential waveforms and in controlling repetitive firing in these cells. Using the biolistic gene gun, cDNAs encoding a mutant Kv4.2 alpha subunit (Kv4.2W362F), which functions as a dominant negative (Kv4.2DN), and enhanced green fluorescent protein (EGFP) were introduced in vitro into neurons isolated from postnatal rat primary visual cortex. Whole-cell voltage-clamp recordings obtained from EGFP-positive pyramidal neurons revealed that IA is selectively eliminated in cells expressing Kv4.2DN. The densities and properties of the other Kv currents are unaffected. In neurons expressing Kv4.2DN, input resistances are increased and the (current) thresholds for action potential generation are decreased. In addition, action potential durations are prolonged, the amplitudes of afterhyperpolarizations are reduced, and the responses to prolonged depolarizing inputs are altered markedly in cells expressing Kv 4.2DN. At low stimulus intensities, firing rates are increased in Kv4.2DN-expressing cells, whereas at high stimulus intensities, Kv4.2DN-expressing cells adapt strongly. Together, these results demonstrate that Kv4alpha subunits encode IA channels and that IA plays a pivotal role in shaping the waveforms of individual action potentials and in controlling repetitive firing in visual cortical pyramidal neurons.

Published

2005

11. Mediation of neuronal apoptosis by Kv2.1-encoded potassium channels.

Author

Pal S, Hartnett KA, Nerbonne JM, Levitan ES, and Aizenman E

Subjects

Animals, Apoptosis drug effects, CHO Cells, Cells, Cultured, Cricetinae, Cytoprotection genetics, Cytoprotection physiology, Delayed Rectifier Potassium Channels, Genes, Dominant, Neurons cytology, Oxidants toxicity, Patch-Clamp Techniques, Potassium metabolism, Potassium Channels genetics, Protein Subunits genetics, Protein Subunits metabolism, Rats, Shab Potassium Channels, Signal Transduction drug effects, Signal Transduction physiology, Staurosporine toxicity, Transfection, Apoptosis physiology, Neurons metabolism, Potassium Channels metabolism, Potassium Channels, Voltage-Gated

Abstract

Cellular K+ efflux is a requisite event in the unfolding of apoptosis programs across many types of cells and death-inducing stimuli; however, the molecular identities of the ion channels mediating this key event have remained undefined. Here, we show that Kv2.1-encoded K+ channels are responsible for the expression of apoptosis in cortical neurons in vitro. Transient expression of two different dominant-negative forms of this subunit in neurons completely eliminated the enhancement of K+ currents that normally accompanies the cell death process. Importantly, neurons deficient in functional Kv2.1-encoded K+ channels were protected from oxidant and staurosporine-induced apoptosis. Finally, Chinese hamster ovary cells, which do not express endogenous voltage-gated K+ channels, became substantially more sensitive to apoptosis after transient expression of wild-type Kv2.1. These results suggest that Kv2.1-encoded K+ channels are necessary for the apoptotic signaling cascade in mammalian cortical neurons in culture and are sufficient for increasing the susceptibility to apoptogens in a nonexcitable cell.

Published

2003

12. Delayed rectifier K+ currents, IK, are encoded by Kv2 alpha-subunits and regulate tonic firing in mammalian sympathetic neurons.

Author

Malin SA and Nerbonne JM

Subjects

Action Potentials physiology, Animals, Biolistics, Cells, Cultured, Delayed Rectifier Potassium Channels, Genes, Dominant, Humans, Kidney cytology, Kidney metabolism, Mutagenesis, Site-Directed, Neurons cytology, Patch-Clamp Techniques, Potassium metabolism, Potassium Channels genetics, Protein Subunits genetics, Rats, Rats, Long-Evans, Shab Potassium Channels, Superior Cervical Ganglion cytology, Superior Cervical Ganglion metabolism, Sympathetic Nervous System cytology, Neurons metabolism, Potassium Channels metabolism, Potassium Channels, Voltage-Gated, Protein Subunits metabolism, Sympathetic Nervous System metabolism, Synaptic Transmission physiology

Abstract

Previous studies have revealed the presence of four kinetically distinct voltage-gated K+ currents, I(Af), I(As), I(K), and I(SS), in rat superior cervical ganglion (SCG) neurons and demonstrated that I(K) and I(SS) are expressed in all cells, whereas I(Af) and I(As) are differentially distributed. Previous studies have also revealed the presence of distinct components of I(Af) encoded by alpha-subunits of the Kv1 and Kv4 subfamilies. In the experiments described here, pore mutants of Kv2.1 (Kv2.1W365C/Y380T) and Kv2.2 (Kv2.2W373C/Y388T) that function as Kv2 subfamily-specific dominant negatives (Kv2.1DN and Kv2.2DN) were generated to probe the functional role(s) of Kv2 alpha-subunits. Expression of Kv2.1DN or Kv2.2DN in human embryonic kidney-293 cells selectively attenuates Kv2.1- or Kv2.2-encoded K+ currents, respectively. Using the Biolistics Gene Gun, cDNA constructs encoding either Kv2.1DN or Kv2.2DN [and enhanced green fluorescent protein (EGFP)] were introduced into SCG neurons. Whole-cell recordings from EGFP-positive Kv2.1DN or Kv2.2DN-expressing cells revealed selective decreases in I(K). Coexpression of Kv2.1DN and Kv2.2DN eliminates I(K) in most (75%) SCG cells and, in the remaining (25%) cells, I(K) density is reduced. Together with biochemical data revealing that Kv2.1 and Kv2.2 alpha-subunits do not associate in rat SCGs, these results suggest that Kv2.1 and Kv2.2 form distinct populations of I(K) channels, and that Kv2 alpha-subunits underlie (most of) I(K) in SCG neurons. Similar to wild-type cells, phasic, adapting, and tonic firing patterns are evident in SCG cells expressing Kv2.1DN or Kv2.2DN, although action potential durations in tonic cells are prolonged. Expression of Kv2.2DN also results in membrane depolarization, suggesting that Kv2.1- and Kv2.2-encoded I(K) channels play distinct roles in regulating the excitability of SCG neurons.

Published

2002

13. Molecular heterogeneity of the voltage-gated fast transient outward K+ current, I(Af), in mammalian neurons.

Author

Malin SA and Nerbonne JM

Subjects

Action Potentials physiology, Amino Acid Substitution, Animals, Biolistics, Cells, Cultured, Gene Expression, Genes, Reporter, Green Fluorescent Proteins, Kv1.5 Potassium Channel, Luminescent Proteins genetics, Mutagenesis, Site-Directed, Neurons classification, Neurons cytology, Patch-Clamp Techniques, Potassium Channels genetics, Rats, Rats, Long-Evans, Reaction Time physiology, Sensory Thresholds physiology, Shal Potassium Channels, Superior Cervical Ganglion cytology, Superior Cervical Ganglion metabolism, Neurons metabolism, Potassium metabolism, Potassium Channels biosynthesis, Potassium Channels, Voltage-Gated, Protein Subunits

Abstract

Recently, we identified four kinetically distinct voltage-gated K(+) currents, I(Af), I(As), I(K), and I(SS), in rat superior cervical ganglion (SCG) neurons and demonstrated that I(Af) and I(As) are differentially expressed in type I (I(Af), I(K), I(SS)), type II (I(Af), I(As), I(K), I(SS)), and type III (I(K), I(SS)) SCG cells. In addition, we reported that I(Af) is eliminated in most ( approximately 70%) SCG cells expressing Kv4.2W362F, a Kv4 subfamily-specific dominant negative. The molecular correlate(s) of the residual I(Af), as well as that of I(As), I(K), and I(SS), however, are unknown. The experiments here were undertaken to explore the role of Kv1 alpha-subunits in the generation of voltage-gated K(+) currents in SCG neurons. Using the Biolistics Gene Gun, cDNA constructs encoding a Kv1 subfamily-specific dominant negative, Kv1.5W461F, and enhanced green fluorescent protein (EGFP) were introduced into SCG neurons. Whole-cell recordings from EGFP-positive Kv1.5W461F-expressing cells revealed a selective decrease in the percentage of type I cells and an increase in type III cells, indicating that I(Af) is gated by Kv1 alpha-subunits in a subset of type I SCG neurons. I(Af) is eliminated in all SCG cells expressing both Kv1.5W461F and Kv4.2W362F. I(Af) tau(decay) values in Kv1.5W461F-expressing and Kv4.2W362F-expressing type I cells are significantly different, revealing that Kv1 and Kv4 alpha-subunits encode kinetically distinct I(Af) channels. Expression of Kv1.5W461F increases excitability by decreasing action potential current thresholds and converts phasic cells to adapting or tonic firing. Interestingly, the molecular heterogeneity of I(Af) channels has functional significance because Kv1- and Kv4-encoded I(Af) play distinct roles in the regulation of neuronal excitability.

Published

2001

14. Elimination of the fast transient in superior cervical ganglion neurons with expression of KV4.2W362F: molecular dissection of IA.

Author

Malin SA and Nerbonne JM

Subjects

Action Potentials, Adaptation, Physiological, Animals, Biolistics, Cell Count, Cells, Cultured, Coculture Techniques, Green Fluorescent Proteins, Ion Transport physiology, Luminescent Proteins biosynthesis, Luminescent Proteins genetics, Mutagenesis, Site-Directed, Neuroglia cytology, Neurons cytology, Patch-Clamp Techniques, Potassium metabolism, Potassium Channels genetics, Rats, Rats, Long-Evans, Recombinant Proteins biosynthesis, Recombinant Proteins genetics, Shal Potassium Channels, Superior Cervical Ganglion cytology, Neurons metabolism, Potassium Channels biosynthesis, Potassium Channels, Voltage-Gated, Superior Cervical Ganglion metabolism

Abstract

Electrophysiological and molecular studies have revealed considerable heterogeneity in voltage-gated K(+) currents and in the subunits that underlie these channels in mammalian neurons. At present, however, the relationship between native K(+) currents and cloned subunits is poorly understood. In the experiments here, a molecular genetic approach was exploited to define the molecular correlate of the fast transient outward K(+) current, I(Af), in sympathetic neurons and to explore the functional role of I(Af) in shaping action potential waveforms and controlling repetitive firing patterns. Using the biolistic gene gun, cDNAs encoding a dominant negative mutant Kv4.2 alpha-subunit (Kv4.2W362F) and enhanced green fluorescent protein (EGFP) were introduced into rat sympathetic neurons in vitro. Whole-cell voltage-clamp recordings obtained from EGFP-positive cells revealed that I(Af) is selectively eliminated in cells expressing Kv4.2W362F, demonstrating that Kv4 alpha-subunits underlie I(Af) in sympathetic neurons. In addition, I(Af) density is increased significantly in cells overexpressing wild-type Kv4.2. In cells expressing Kv4.2W362F, input resistances are increased and (current) thresholds for action potential generation are decreased, demonstrating that I(Af) plays a pivotal role in regulating excitability. Expression of Kv4.2W362F and elimination of I(Af) also alters the distribution of repetitive firing patterns observed in response to a prolonged injection of depolarizing current. The wild-type superior cervical ganglion is composed of phasic, adapting, and tonic firing neurons. Elimination of I(Af) increases the percentage of adapting cells by shifting phasic cells to the adapting firing pattern, and increased I(Af) density reduces the number of adapting cells.

Published

2000

15. Differential expression of hyperpolarization-activated currents reveals distinct classes of visual cortical projection neurons.

Author

Solomon JS, Doyle JF, Burkhalter A, and Nerbonne JM

Subjects

Animals, Electric Conductivity, Neurons physiology, Rats, Synaptic Transmission, Visual Cortex physiology, Visual Pathways physiology, Corpus Callosum physiology, Superior Colliculi physiology, Synapses physiology

Abstract

Combining in vivo retrograde labeling and in vitro electrophysiological recording techniques, we examined the distributions, densities, and biophysical properties of hyperpolarization-activated inward currents in two types of isolated, identified visual cortical projection neurons, superior colliculus-projecting (SCP) and callosal-projecting (CP) cells. In SCP cells, two kinetically distinct time-dependent hyperpolarization-activated inward current components are present. We have termed these Ih,f and Ih,s to denote the fast and slow components, respectively, of Ih activation. In CP cells, in contrast, Ih,f and Ih,s are differentially expressed. In 59% of the CP cells examined, for example, both Ih,f and Ih,s were present. The properties of the currents are indistinguishable from those recorded from SCP cells, although both Ih,f and Ih,s are expressed at significantly lower densities in this subset of CP cells (as compared to the current densities in SCP cells). Of the remaining 41% of the CP cells studied, 26% were found to express only Ih,s, and 12% of the cells expressed neither Ih,f nor Ih,s. Taken together, these results reveal that the electrical properties of CP visual cortical neurons are considerably more heterogeneous than those of SCP cells. The differential expression of Ih,f and Ih,s is expected to influence the integrated responses of different types of cortical projection neurons to excitatory and inhibitory synaptic inputs.

Published

1993

16. Development of excitable membrane properties in mammalian sympathetic neurons.

Author

Nerbonne JM and Gurney AM

Subjects

Action Potentials, Animals, Animals, Newborn physiology, Cell Membrane physiology, Cells, Cultured, Electric Stimulation, Electrophysiology, Embryo, Mammalian physiology, Ganglia, Sympathetic cytology, Ion Channel Gating, Membrane Potentials, Neurons ultrastructure, Rats, Sodium Channels physiology, Ganglia, Sympathetic physiology, Neurons physiology

Abstract

Using the whole-cell patch-clamp recording technique, resting membrane potentials (RPs), action potential (AP) waveforms, and the properties of voltage-activated inward Na+ (lNa) and Ca2+ (lCa) currents and outward K+ (lA,lK) currents were examined in embryonic and neonatal rat superior cervical ganglion (SCG) neurons as a function of time during development in vivo and in vitro. The passive and active membrane properties of neonatal SCG cells examined less than or equal to 24 hr after isolation were similar to those described previously for adult SCG neurons and for neonatal SCG cells maintained for several weeks in culture. Since recordings were obtained within hours of cell dissociations, it is assumed that the results reflect the membrane properties of neonatal SCG neurons in vivo at the time of isolation. When neonatal cells were examined as a function of time (up to approximately 2-3 weeks) in vitro, neither RPs nor AP waveforms varied measurably. Although absolute (inward and outward) current amplitudes increased in cells maintained in vitro, in parallel with increases in cell size, no changes in the time- or voltage-dependent properties of the currents were observed. Similar results were obtained for cells isolated on or after embryonic day 18.5 (greater than or equal to E 18.5). The membrane properties of E 14.5-16.5 SCG cells examined less than or equal to 24 hr after isolation, in contrast, were significantly different: mean lCa density was higher, and APs were broader than in greater than or equal to E 18.5 cells, and, in addition, lA was absent in these cells. When E 14.5-16.5 cells were examined after approximately 1 week in vitro, lCa densities and AP waveforms were indistinguishable from those in greater than or equal to E 18.5 SCG neurons, and lA was present. These studies reveal that rat SCG neurons are electrophysiologically mature early in development. Even lA, which seems to be the last voltage-gated current to develop, appears well before birth. As the appearance of lA correlates with decreased membrane excitability and AP shortening, it seems likely that the development of lA either reflects or regulates a marked change in the overall input and output properties of developing sympathetic neurons.

Published

1989

17. Blockade of Ca2+ and K+ currents in bag cell neurons of Aplysia californica by dihydropyridine Ca2+ antagonists.

Author

Nerbonne JM and Gurney AM

Subjects

Animals, Aplysia, Calcium antagonists & inhibitors, Ion Channels radiation effects, Kinetics, Mathematics, Neurons drug effects, Nisoldipine, Potassium antagonists & inhibitors, 3-Pyridinecarboxylic acid, 1,4-dihydro-2,6-dimethyl-5-nitro-4-(2-(trifluoromethyl)phenyl)-, Methyl ester pharmacology, Calcium metabolism, Calcium Channel Blockers pharmacology, Dihydropyridines, Ion Channels drug effects, Neurons metabolism, Nifedipine analogs & derivatives, Nifedipine pharmacology, Potassium metabolism, Pyridines pharmacology

Abstract

The effects of dihydropyridine calcium antagonists on whole-cell Ca2+ and K+ currents in the neurosecretory bag cells of the marine mollusc Aplysia californica have been investigated. Nifedipine and nisoldipine blocked bag cell Ca2+ currents with effects similar to those seen previously on Ca2+ currents in cardiac muscle: both compounds appeared to interact with Ca2+ channels when they were closed, open, and inactivated. Also, as seen in cardiac cells, nifedipine apparently binds with higher affinity to Ca2+ channels when they are inactivated than when they are either closed or open. Nifedipine and nisoldipine also inhibited 2 outward K+ currents in bag cells: the "delayed rectifier" (IK) and the "A" (IA) currents. Half-maximal blockade of Ca2+ currents occurred at approximately 1.4 microM nifedipine, compared to approximately 3-5 microM for half-maximal blockade of IK and IA. The effects of these compounds on bag cell Ca2+ and K+ currents are interpreted and discussed here in terms of the "modulated receptor" model of drug action. In contrast, however, no measurable effects of nifedipine or nisoldipine were seen on Ca2+ (and/or K+) currents in several vertebrate neuronal cell types. Our results suggest that there are likely to be structural and/or conformational variations in Ca2+ channels in different cells, tissues, and/or species and also that, in some cells, Ca2+ and K+ channels might be structurally similar. These findings also suggest, therefore, that if dihydropyridine binding is used to identify Ca2+ channels, care should be taken to ensure that binding correlates closely with the Ca2+ channels of interest.

Published

1987