Regulation of cation channel voltage- and Ca2+-dependence in Aplysia bag cell neurons

Gardam, Kate Elizabeth

27 August 2008

Ion channel regulation is key to the control of excitability and behaviour. In the bag cell neurons of Aplysia californica, a voltage- and Ca2+-dependent nonselective cation channel drives a ~30-minute afterdischarge, culminating in the release of egg-laying hormone. Using excised, inside-out single channel patch-clamp, this study tested the hypothesis that inositol 1,4,5-trisphosphate (IP3), which is produced during the afterdischarge, and channel-associated protein kinase C (PKC), which is activated throughout the afterdischarge, cause a left-shift (enhancement) in both the voltage- and Ca2+-dependence of the cation channel. Kinetic analysis of bag cell neuron cation channel voltage-dependence revealed that, with depolarization, the channel remained open longer and reopened more often. A cation channel subconductance was also observed, and found to be 13 pS vs. the typical 23 pS full-conductance. The cytoplasmic face of cation channel-containing patches was exposed to 1 mM ATP, as a phosphate source for channel-associated PKC, and/or 5 uM IP3. Apparent PKC-dependent phosphorylation left-shifted voltage-dependence by -3 mV, although this effect was more prominent at negative voltages (between -90 and -30 mV). Conversely, IP3 right-shifted voltage-dependence (change in V1/2 of 6 mV). Cation channel Ca2+-dependence was similar to that previously reported, with a control EC50 of 3-5 uM. This was right-shifted by PKC (EC50 = 30 uM) and even more so by IP3 (apparent EC50 = 20 M). PKC largely rescued the Ca2+ responsiveness in the presence of IP3 (EC50 = 20 uM). Unexpectedly, IP3 plus ATP resulted in an increase in channel unitary conductance at more positive voltages. The multi-faceted regulation of the bag cell neuron cation channel suggests sophisticated modulatory control. Upregulation, such as depolarization and the left-shift in voltage-dependence with PKC, would drive the afterdischarge, while counteracting effects, such as IP3 right-shifting voltage-dependence, as well as PKC and IP3 suppressing Ca2+-dependence, would simultaneously or subsequently attenuate the channel, thus preventing an interminable afterdischarge. / Thesis (Master, Physiology) -- Queen's University, 2008-08-26 13:20:16.528

Neuronal excitability

Ion channel regulation

Comparative Anatomical and Biophysical Characterization of a Hippocampal-like Network in Teleost and Rodents

Trinh, Anh-Tuân

13 August 2021

The work presented in this thesis investigates whether primitive pallial brain circuits such as those found in teleost fish may also encode complex information such as spatial memory despite its circuitry being “simpler” than those found in species with much larger brains such as primates and rodents. Previous behavioral studies have already shown that most teleost fish are capable of spatially orienting themselves and remembering past food locations. Behavioral studies combined with selective brain lesions and related anatomical studies have identified a hippocampal-like region in the fish’s pallium; however, it is unknown whether the neurons located in this structure can also perform cortical-like computations as those found in the mammalian hippocampus. Consequently, this thesis will first present an anatomical characterization of the intrinsic circuitry of this hippocampal-like structure, followed by an in vitro electrophysiological characterization of its constituent neurons. Surprisingly, we have found that this hippocampal-like structure possesses many features reminiscent of the mammalian cortex, including recurrent local connectivity as well as a laminar/columnar-like organization. Furthermore, we have also identified many biophysical properties which would describe these hippocampal-like neurons as sparse coders, including a prominent after-hyperpolarizing potential and an adapting spike threshold with slow recovery. Since this particular dynamic spike threshold mechanism has not been thoroughly characterized in the mammalian hippocampus, we have further investigated the dynamic threshold in the major rodent hippocampal cell types. We have found that only a subset of excitatory neurons displayed this dynamic spike threshold on the time scale that was observed in teleost pallial cells, which allowed us to discuss its potential role in encoding spatial information in both species. Nevertheless, the fact that this teleost hippocampal homologue possesses characteristics that are both akin to the cortex and hippocampus suggest that it may perform computations that, in a mammalian brain, would require both structures and makes this ancestral structure a very interesting candidate to study the mechanism(s) underlying spatial memory.

Neuroscience

Comparative neuroanatomy

Electrophysiology

Hippocampus

Spatial memory

Neuronal excitability

Fish

The Regulation of Neuronal Excitability and Nociception by Tonic GABAergic Inhibition

Bonin, Robert

23 July 2013

The mammalian central nervous system maintains a delicate balance between neuronal excitation and inhibition. Conventional synaptic inhibition is mediated through the transient activity of postsynaptic γ-aminobutyric acid (GABA) at type A GABA (GABAA) receptors. A subset of GABAA receptors is also located outside of inhibitory synapses. These extrasynaptic receptors generate a tonic inhibitory conductance in response to low concentrations of extracellular GABA. Tonic inhibition broadly suppresses neuronal activity and regulates many vital processes such as sleep, consciousness and memory formation. This thesis examines the physiological effects of tonic inhibition at the cellular level and in the behaving animal. This thesis also explores whether gabapentin, a commonly used sedative, anxiolytic, and analgesic drug, enhances tonic GABAergic inhibition. I hypothesize that: (1) tonic GABAA receptor activity reduces the intrinsic excitability of neurons; (2) the activity of tonically active GABAA receptors in spinal pain pathways attenuates nociception; and (3) tonic inhibition can be upregulated by gabapentin. The results show that a tonic inhibitory current generated by α5 subunit-containing GABAA (α5GABAA) receptors reduces the excitability of hippocampal pyramidal neurons excitability by increasing the rheobase, but does not change the gain of action potential firing. A similar shunting inhibition is present in spinal cord lamina II neurons that is generated by δ subunit-containing GABAA receptors. The activity of these receptors in spinal nociceptive pathways reduces acute thermal nociception and may constrain central sensitization in a behavioural model of persistent pain. Finally, gabapentin increases a tonic inhibitory current in cultured hippocampal neurons independent from changes in the expression of α5GABAA receptors or in the concentration of GABAA receptor ligands. The results of this thesis demonstrate that tonically active GABAA receptors play an important role in the regulation of neuronal activity and nociception, and that tonic inhibition represents a novel target of therapeutic drugs.

GABA

neuronal excitability

dorsal horn

tonic inhibition

nociception

gabapentin

0317

0719

Persistent and transient Na⁺ currents in hippocampal CA1 pyramidal neurons

Park, Yul Young

13 October 2011

The biophysical properties and distribution of voltage gated ion channels shape the spatio-temporal pattern of synaptic inputs and determine the input-output properties of the neuron. Of the various voltage-gated ion channels, persistent Na⁺ current (INaP) is of interest because of its activation near rest, slow inactivation kinetics, and consequent effects on excitability. Overshadowed by transient Na⁺ current (INaT) of large amplitude and fast inactivation, various quantitative characterizations of INaP have yet to provide a clear understanding of their role in neuronal excitability. We addressed this question using quantitative electrophysiology to compare somatic INaP and INaT in 4–7 week old Sprague-Dawley rat hippocampal CA1 pyramidal neurons. INaP was evoked with 0.4 mV/ms ramp voltage commands and INaT with step commands in hippocampal neurons from in vitro brain slices utilizing nucleated patch-clamp recording. INaP was found to have a density of 1.4 ± 0.7 pA/pF in the soma. Compared to INaT, it has a much smaller amplitude (2.38% of INaT) and distinct voltage dependence of activation (16.7 mV lower half maximal activation voltage and 41.3% smaller slope factor than those of INaT). The quantitative measurement of INaT gave the activation time constant ([tau]m) of 22.2 ± 2.3 [mu]s at 40 mV. Hexanol, which has anesthetic effects, was shown to preferentially block INaP compared to INaT with a significant voltage threshold elevation (4.6 ± 0.7 mV) and delayed 1st spike latency (221 ± 54.6 ms) suggesting reduced neuronal excitability. The number of spikes evoked by either given step current injections or [alpha]-EPSP integration was also significantly decreased. The differential blocking of INaP by halothane, a popularly used volatile anesthetic, further supports the critical role of INaP in setting voltage threshold. Taken together, the presence of INaP in the soma demonstrates an intrinsic mechanism utilized by hippocampal CA1 pyramidal neurons to regulate axonal spike initiation through different biophysical properties of the Na⁺ channel. Furthermore, INaP becomes an interesting target of intrinsic plasticity because of its profound effect on the input-output function of the neuron. / text

Persistent sodium current

Transient sodium current

Hippocampus

Neuronal excitability

Hexanol

Riluzole

Ranolazine

The Regulation of Neuronal Excitability and Nociception by Tonic GABAergic Inhibition

Bonin, Robert

23 July 2013

The mammalian central nervous system maintains a delicate balance between neuronal excitation and inhibition. Conventional synaptic inhibition is mediated through the transient activity of postsynaptic γ-aminobutyric acid (GABA) at type A GABA (GABAA) receptors. A subset of GABAA receptors is also located outside of inhibitory synapses. These extrasynaptic receptors generate a tonic inhibitory conductance in response to low concentrations of extracellular GABA. Tonic inhibition broadly suppresses neuronal activity and regulates many vital processes such as sleep, consciousness and memory formation. This thesis examines the physiological effects of tonic inhibition at the cellular level and in the behaving animal. This thesis also explores whether gabapentin, a commonly used sedative, anxiolytic, and analgesic drug, enhances tonic GABAergic inhibition. I hypothesize that: (1) tonic GABAA receptor activity reduces the intrinsic excitability of neurons; (2) the activity of tonically active GABAA receptors in spinal pain pathways attenuates nociception; and (3) tonic inhibition can be upregulated by gabapentin. The results show that a tonic inhibitory current generated by α5 subunit-containing GABAA (α5GABAA) receptors reduces the excitability of hippocampal pyramidal neurons excitability by increasing the rheobase, but does not change the gain of action potential firing. A similar shunting inhibition is present in spinal cord lamina II neurons that is generated by δ subunit-containing GABAA receptors. The activity of these receptors in spinal nociceptive pathways reduces acute thermal nociception and may constrain central sensitization in a behavioural model of persistent pain. Finally, gabapentin increases a tonic inhibitory current in cultured hippocampal neurons independent from changes in the expression of α5GABAA receptors or in the concentration of GABAA receptor ligands. The results of this thesis demonstrate that tonically active GABAA receptors play an important role in the regulation of neuronal activity and nociception, and that tonic inhibition represents a novel target of therapeutic drugs.

GABA

neuronal excitability

dorsal horn

tonic inhibition

nociception

gabapentin

0317

0719

Bloqueio dos receptores β1 - adrenérgicos periféricos impede o desenvolvimento da ansiedade tardia induzida por estresse em ratos Wistar. / The blockage of peripheral β1-adrenergic receptors prevents the restraint stress-induced long-lasting anxiety in wistar rats.

Perfetti, Juliano Genaro

08 June 2016

INTRODUÇÃO: o estresse, causa importante de ansiedade, provoca ativação do eixo HPA, liberando hormônios glicocorticoides e adrenalina, e neurotransmissores, como a norepinefrina. Consequentemente, ocorrem mudanças morfológicas e biomoleculares em diversas regiões do SNC, destacando-se o complexo basolateral da amígdala, além de alterações comportamentais. OBJETIVOS: investigar, por meio de administrações (ip) de atenolol e metirapona, possíveis influências periféricas dos receptores de NE (&#946;1) e GR no BLA de ratos na ansiedade tardia. Analisar também a via de sinalização intracelular ERK-MEK-CREB e a excitabilidade de neurônios da região. RESULTADOS: verificamos aumento do estado do tipo ansioso após 10 dias do estresse, efeito não visto com tratamento com atenolol (ip). Além disso, o estresse provocou aumento de EGR1 (p<0.05), dado indicador de maior taxa de atividade de neurônios do BLA, efeito não encontrado nos animais tratados com atenolol. Além disso, não encontramos alterações na fosforilação de ERK e na espressão de CREB. CONCLUSÃO: a sinalização adrenérgica/noradrenérgica periférica pode ter relevante função na modulação do comportamento do tipo ansioso tardio (10 dias) induzido por um único estresse de contenção. / INTRODUCTION: stress, an important cause of anxiety, triggers HPA activation, releasing epinephrine and glucocorticoids (GCs) hormones and neurotransmitters such as norepinephrine (NE). As result, morphological and biomolecular changes occurs in several regions of CNS, majorly in the amygdala basolateral complex, in addition to behaviors alterations. OBJECTIFS: to investigate, using atenolol and metyrapone administration (ip), the influence of NE receptors (&#946;1) and GR, respectively, in the BLA of rats in the restraint stress-induced long-lasting anxiety. In addition, also investigate the participation of ERK-MEK-CREB signaling and neuronal BLA excitability in such paradigm. RESULTS: we showed that restraint stress (2h) induced anxiety-like behavior 10 days after stress, and the pre-treatment with atenolol blunted such effect. In addition, we observed that restraint stress increased the expression of EGR1 (p<0.05) in the BLA of stressed rats, which was also blunted by atenolol administration, suggesting a higher activity in BLA neurons. We found no modulation in ERK and CREB activation in restraint stress-induced long-lasting anxiety rats. CONCLUSION: we conclude that the peripheral adrenergic/noradrenergic signaling may have a relevant function in long-lasting anxiety-like behavior (10 days) induced by a single episode of restraint stress.

Adrenergic receptors

Amygdala basolateral complex

Ansiedade

Anxiety

Complexo basolateral da amígdala

Estresse psicológico

Excitabilidade neuronal

Neuronal excitability

Psychological stress

Receptores adrenérgicos

Ras-dependent and Ras-independent effects of PI3K in Drosophila motor neurons

January 2012

The lipid kinase PI3K plays key roles in cellular responses to activation of receptor tyrosine kinases or G protein coupled receptors such as the metabotropic glutamate receptor (mGluR). Activation of the PI3K catalytic subunit p110 occurs when the PI3K regulatory subunit p85 binds to phosphotyrosine residues present in upstream activating proteins. In addition, Ras is uniquely capable of activating PI3K in a p85-independent manner by binding to p110 at amino acids distinct from those recognized by p85. Because Ras, like p85, is activated by phosphotyrosines in upstream activators, it can be difficult to determine if particular PI3K-dependent processes require p85 or Ras. Here we ask if PI3K requires Ras activity for either of two different PI3K-regulated processes within Drosophila larval motor neurons. To address this question, we determined the effects on each process of transgenes and chromosomal mutations that decrease Ras activity, or mutations that eliminate the ability of PI3K to respond to activated Ras. We found that PI3K requires Ras activity to decrease motor neuron excitability, an effect mediated by ligand activation of the single Drosophila mGluR DmGIuRA. In contrast, the ability of PI3K to increase synaptic bouton number is Ras independent. These results suggest that distinct regulatory mechanisms underlie the effects of PI3K on distinct phenotypic outputs. We additionally found that the glutamate-activation of DmGIuRA initiates ERK signaling; however the signaling intermediates linking DmGIuRA to this kinase cascade are unknown.

Biological sciences

Drosophila

Fragile X

Synaptic bouton number

Neuronal excitability

Metabotropic glutamate receptor

Autism

Ras

Neurosciences

Genetics

Cellular biology

Bloqueio dos receptores &#946;1 - adrenérgicos periféricos impede o desenvolvimento da ansiedade tardia induzida por estresse em ratos Wistar. / The blockage of peripheral &#946;1-adrenergic receptors prevents the restraint stress-induced long-lasting anxiety in wistar rats.

Juliano Genaro Perfetti

08 June 2016

INTRODUÇÃO: o estresse, causa importante de ansiedade, provoca ativação do eixo HPA, liberando hormônios glicocorticoides e adrenalina, e neurotransmissores, como a norepinefrina. Consequentemente, ocorrem mudanças morfológicas e biomoleculares em diversas regiões do SNC, destacando-se o complexo basolateral da amígdala, além de alterações comportamentais. OBJETIVOS: investigar, por meio de administrações (ip) de atenolol e metirapona, possíveis influências periféricas dos receptores de NE (&#946;1) e GR no BLA de ratos na ansiedade tardia. Analisar também a via de sinalização intracelular ERK-MEK-CREB e a excitabilidade de neurônios da região. RESULTADOS: verificamos aumento do estado do tipo ansioso após 10 dias do estresse, efeito não visto com tratamento com atenolol (ip). Além disso, o estresse provocou aumento de EGR1 (p<0.05), dado indicador de maior taxa de atividade de neurônios do BLA, efeito não encontrado nos animais tratados com atenolol. Além disso, não encontramos alterações na fosforilação de ERK e na espressão de CREB. CONCLUSÃO: a sinalização adrenérgica/noradrenérgica periférica pode ter relevante função na modulação do comportamento do tipo ansioso tardio (10 dias) induzido por um único estresse de contenção. / INTRODUCTION: stress, an important cause of anxiety, triggers HPA activation, releasing epinephrine and glucocorticoids (GCs) hormones and neurotransmitters such as norepinephrine (NE). As result, morphological and biomolecular changes occurs in several regions of CNS, majorly in the amygdala basolateral complex, in addition to behaviors alterations. OBJECTIFS: to investigate, using atenolol and metyrapone administration (ip), the influence of NE receptors (&#946;1) and GR, respectively, in the BLA of rats in the restraint stress-induced long-lasting anxiety. In addition, also investigate the participation of ERK-MEK-CREB signaling and neuronal BLA excitability in such paradigm. RESULTS: we showed that restraint stress (2h) induced anxiety-like behavior 10 days after stress, and the pre-treatment with atenolol blunted such effect. In addition, we observed that restraint stress increased the expression of EGR1 (p<0.05) in the BLA of stressed rats, which was also blunted by atenolol administration, suggesting a higher activity in BLA neurons. We found no modulation in ERK and CREB activation in restraint stress-induced long-lasting anxiety rats. CONCLUSION: we conclude that the peripheral adrenergic/noradrenergic signaling may have a relevant function in long-lasting anxiety-like behavior (10 days) induced by a single episode of restraint stress.

Ansiedade

Complexo basolateral da amígdala

Estresse psicológico

Excitabilidade neuronal

Receptores adrenérgicos

Adrenergic receptors

Amygdala basolateral complex

Anxiety

Neuronal excitability

Psychological stress

Diversité des mécanismes de stabilisation du segment initial de l'axone

Montersino, Audrey

05 December 2013

Le segment initial de l’axone (SIA) est un sous-domaine fonctionnel du neurone localisé dans l’axone proximal, qui assure deux fonctions : l’initiation du potentiel d’action et le maintien de l’identité axonale. Le maintien et la stabilité du SIA sont des éléments fondamentaux de l’excitabilité du neurone et la nature dynamique de l’organisation fonctionnelle du SIA a été mise en évidence. Les objectifs de mes travaux de thèse ont été d’étudier les mécanismes responsables du maintien du SIA, en condition physiologique ou pathologique et d’identifier de nouveaux acteurs impliqués dans ces mécanismes. Dans un premier temps, nous avons identifié et caractérisé l’expression d’une nouvelle protéine au SIA : la protéine Scrib1. En utilisant une approche par ARN interférent nous avons montré que Scrib1 est nécessaire au maintien de la morphologie du SIA. Les conséquences fonctionnelles de l’absence de Scrib1 sont une diminution de l’excitabilité neuronale. Dans un second temps, nous nous sommes intéressés aux mécanismes pouvant être à l’origine de l’expression ectopique du canal Nav1.8 observée dans certaines pathologies démyélinisantes. Nous avons montré que Nav1.8 possède un site d’interaction à l’ankyrine G. Ce motif d’interaction est suffisant pour adresser un canal chimérique au SIA et perturber l’expression des Nav1 endogènes. A l’inverse des Nav1 du système nerveux central, l’interaction entre Nav1.8 et l’ankyrine G n’est pas régulée par la CK2. Cette interaction constitutive entre Nav1.8 et l’ankyrine G pourrait expliquer son expression ectopique dans le système nerveux central. / The axonal initial segment (AIS) is a unique sub-domain that plays a central role in the physiology of the neuron, as it orchestrates both electrogenesis and the maintenance of neuronal polarity. The maintenance and the stability of the AIS after assembly ensure a reliable generation of action potentials. However, new mechanisms affecting AIS protein-protein interaction and composition have been shown to modulate the electrogenesis of the neuron. Moreover, recent findings highlight that the AIS is capable of homeostatic plasticity through an activity–dependent change either in its location along the proximal axon or in its length. The objectives of my thesis were to study the mechanisms responsible for AIS maintenance in physiological or pathological condition and to identify new players involved in these mechanisms.First we identified and characterized the expression of a novel protein in AIS: the protein Scrib1. Using an shRNA approach we showed that Scrib1 is necessary to maintain the AIS morphology. The functional consequence of the absence of Scrib1 is a decreased of neuronal excitability.Second, we are interested in the mechanisms that cause the ectopic expression of Nav1.8 channel observed in demyelinating diseases. We found that Nav1.8 constitutively interacts with ankG in contrast to Nav1.2, which requires CK2 phosphorylation to bind ankG. Furthermore, when Nav1.8 ankyrin-binding domain was expressed in hippocampal neuron, it clustered at the AIS where it acted as a dominant negative for endogenous Nav1. This constitutive interaction between Nav1.8 and ankG could explain the ectopic expression of Nav1.8 in the central nervous system.

Neurone

Segment initial de l'axone

Excitabilité neuronale

Canaux ioniques dépendants du voltage

Complexe de polarité

Neuron

Axon initial segment

Neuronal excitability

Voltage gated sodium channels

Polarity complex

Pathological synchronization in neuronal populations : a control theoretic perspective

Franci, Alessio

06 April 2012

In the first part of this thesis, motivated by the development of deep brain stimulation for Parkinson's disease, we consider the problem of reducing the synchrony of a neuronal population via a closed-loop electrical stimulation. This, under the constraints that only the mean membrane voltage of the ensemble is measured and that only one stimulation signal is available (mean-field feedback). The neuronal population is modeled as a network of interconnected Landau-Stuart oscillators controlled by a linear single-input single-output feedback device. Based on the associated phase dynamics, we analyze existence and robustness of phase-locked solutions, modeling the pathological state, and derive necessary conditions for an effective desynchronization via mean-field feedback. Sufficient conditions are then derived for two control objectives: neuronal inhibition and desynchronization. Our analysis suggests that, depending on the strength of feedback gain, a proportional mean-field feedback can either block the collective oscillation (neuronal inhibition) or desynchronize the ensemble.In the second part, we explore two possible ways to analyze related problems on more biologically sound models. In the first, the neuronal population is modeled as the interconnection of nonlinear input-output operators and neuronal synchronization is analyzed within a recently developed input-output approach. In the second, excitability and synchronizability properties of neurons are analyzed via the underlying bifurcations. Based on the theory of normal forms, a novel reduced model is derived to capture the behavior of a large class of neurons remaining unexplained in other existing reduced models.

Synchronization control

Deep brain stimulation

Mean-field feedback

Kuramoto model

Phase desynchronization

Oscillation inhibition

Neuronal excitability

Reduced neuronal modeling

Input-output neuronal modeling