Development of the Voltage-Gated Sodium and Potassium Currents Underlying Excitability in Zebrafish Skeletal Muscle

Coutts, Christopher

Unknown Date

No description available.

development

voltage-gated ion channels

Development of the Voltage-Gated Sodium and Potassium Currents Underlying Excitability in Zebrafish Skeletal Muscle

Coutts, Christopher

11 1900

Excitable cells display dynamically regulated changes in the properties of ion currents during development. These changes are crucial for the proper maturation of cellular excitability, and therefore have the potential to affect more sophisticated functions, including neural circuits, movements, and behaviors. Zebrafish skeletal muscle is an excellent model for studying the development of ion channels and their contributions to excitability. They possess distinguishable populations of red and white muscle fibers, whose biological functions are well understood. The main objectives of this thesis were: (1) To characterize the development of muscle excitability by examining properties of voltage-gated sodium and potassium currents expressed in embryonic and larval zebrafish during the first week of development. (2) To elucidate some of the mechanisms by which ion current development might be controlled, beginning with activity-dependent and phosphorylation-dependent mechanisms. These objectives were approached using whole-cell electrophysiological techniques to examine the voltage-dependent and kinetic properties of voltage-gated sodium and potassium currents in intact zebrafish skeletal muscle preparations. Mutant sofa potato zebrafish, which lack functional nicotinic acetylcholine receptors, were then utilized to determine whether synaptic activity at the neuromuscular junction is required for proper ion current development. Finally, protein kinases were activated pharmacologically in order to determine whether they were able to modulate ion currents during development. The results revealed that properties of ion currents undergo a developmental progression, including increased current density, accelerated kinetics, and shifts in voltage-dependence; these developments correlated well with the maturation of muscle action potentials and the movements and behaviors they mediate. Sofa potato mutants were found to be deficient in certain aspects of ion current development, but other aspects appeared to be unaffected by a lack of synaptic activity. Protein kinase A demonstrated the ability to drastically reduce potassium current density; however the effects of PKA were similar at all developmental stages. Overall, these findings provide novel insight into the roles played by voltage-gated currents during the development of excitability in zebrafish skeletal muscle, and expand the rapidly growing body of knowledge about ion channel function in general. / Physiology, Cell & Developmental Biology

development

voltage-gated ion channels

Voltage-gating and assembly of split Kv10.1 channels

Tomczak, Adam

22 April 2016

No description available.

571.4

biophysics

potassium channels

voltage-gating

voltage-gated ion channels

Biologie (PPN619462639)

The Organization of Kv2.1 ChannelProteins in the Membrane of Spinal Motoneurons:Regulation by Injury and Cellular Activity

Romer, Shannon Hunt

07 May 2015

No description available.

Neurosciences

Motoneuron

Kv2

Intrinsic Properties

Voltage-gated Ion Channels

Activity-Dependent

Purificação e caracterização da fração neurotóxica da peçonha da anêmona do mar Anthopleura cascaia / Purification and characterization of the neurotoxic fraction from the venom of the sea anemone Anthopleura cascaia

Madio, Bruno

14 June 2012

A peçonha de anêmonas do mar é uma fonte conhecida de compostos bioativos, incluindo peptídeos, que atuam em canais voltagem-dependentes. Foram descritos 4 tipos de neurotoxinas de anêmonas do mar, que atuam em canais NaV e 4 tipos que atuam em canais KV. Essas toxinas têm permitido discriminar subtipos de canais voltagem-dependentes, estreitamente relacionados, e constituem poderosas ferramentas para estudar o funcionamento e estrutura desses canais. Neste estudo, foram isolados e caracterizados três peptídeos da fração neurotóxica da anêmona do mar Anthopleura cascaia. Esses peptídeos foram nomeados como AcaIII1425, AcaIII2970 e AcaIII3090, onde Aca faz referência a espécie e os números seguem os resultados obtidos nas etapas de purificação. A peçonha foi extraída por meio de estímulos elétricos e purificada por gel-filtração (Sephadex G-50) e fase reversa por HPLC (C-18). As massas moleculares foram obtidas por meio de MALDI-TOF, apresentando 3337,4 Da para a AcaIII1425, 4881,7 Da para a AcaIII2970 e 4880,5 Da para AcaIII3090. Através da técnica de voltage-clamp, esses peptídeos foram testados em diferentes subtipos de canais NaV e KV expressados em ovócito de Xenopus. As toxinas AcaIII2970 e AcaIII3090 retardam, de maneira seletiva, a inativação rápida dos subtipos rNaV1.3, mNaV1.6 e hNaV1.5, enquanto que as outras isoformas testadas permaneceram inalteradas. É importantemente salientar que, a AcaIII2970 e AcaIII3090 também foram examinadas no canal de inseto DmNaV1, revelando uma clara \"filo-seletividade\" na eficácia da atividade das toxinas. A AcaIII2970 e AcaIII3090 inibem fortemente a inativação do canal NaV de inseto, resultando em um aumento na amplitude do pico da corrente e removendo completamente a inativação rápida. Para quantificarmos essa \"filo-seletividade\", foram construídas curvas da dependência da concentração no retardo da inativação induzida pelas toxinas AcaIII2970 e AcaIII3090 nos canais em que apresentaram maior eficácia. Os IC50 foram obtidos após a plotagem dos dados em uma curva sigmoidal. Para a AcaIII2970, os seguintes valores de IC50 foram obtidos: DmNaV1 = 162,19 ± 11,22 nM, mNaV1.6 = 645,92 ± 18,52 nM, rNaV1.3 = 572,56 ± 44,96 nM. Para a AcaIII3090, os seguintes valores de IC50 foram obtidos: DmNaV1 = 99,03 ± 9,25 nM, mNaV1.6 = 158,30 ± 33,86 nM, rNaV1.3 = 371,60 ± 6,48 nM. A AcaIII1425 atua, bloqueando, de modo seletivo os subtipos rKV1.1, rKV1.6 e rKV4.3, enquanto que as outras isoformas testadas permaneceram inalteradas. Devido à maior especificidade da toxina AcaIII1425 pelos subtipos rKV1.1 e rKV1.6, foram realizados ensaios de bloqueio da corrente do canal em função da concentração da toxina (curva dose-resposta). Os valores de IC50 para os subtipos rKV1.1 e rKV1.6 são de 7642,98 ±1601,65 nM e 241,65 ±4,27 nM, respectivamente. Desta forma, a AcaIII1425 é cerca de 32 vezes mais potente em canais do subtipo rKV1.6 do que em relação aos canais do subtipo rKV1.1. A estrutura primária das toxinas foram determinadas por degradação de Edman. A sequência parcial da AcaIII2970 e AcaIII3090 revelou que estas são similares a toxinas de canal de sódio do tipo1 de anêmonas do mar. A sequência completa da AcaIII1425 não apresenta similaridade com toxinas de anêmonas do mar, mas é similar a toxinas de Conus e aranha que possuem um motivo estrutural conhecido como ICK. Dessa forma, propomos que a AcaIII1425 seja um novo grupo de toxinas de anêmonas do mar que bloqueiam KV. Dado o ineditismo da toxina AcaIII1425, foram feitos experimentos in silico para obtermos um maior refinamento do mecanismo de interação entre a toxina e o canal rKV1.6. Estes experimentos indicaram que diferentes regiões dos canais KV são importantes para a seletividade e potência da toxina, corroborando com as propostas que vem sendo descritas / The venom of sea anemones is a known source of bioactive compounds, including peptides that act on voltage-gated ion channels. Four types of neurotoxins from sea anemones, acting on NaV channels, and four types acting on KV channels, have been reported. These toxins have developed the ability to discriminate closely related subtypes of voltage-gated channels, making them powerful tools to studying the function and structure of these channels. In this study, we isolated and characterized three peptides of the neurotoxic fraction from the venom of the sea anemone Anthopleura cascaia. These peptides were named as AcaIII1425, and AcaIII2970 AcaIII3090, where Aca refers to the species and the following numbers refer to results obtained in the purification steps. The venom was milked by electric shock and purified by molecular exclusion (Sephadex G-50) and reverse phase HPLC (C-18). Their molecular weights are 3337.4 Da to AcaIII1425, 4881.7 Da to AcaIII2970 and 4880.5 Da to AcaIII3090, obtained through a MALDI-TOF. Using the voltage-clamp technique, we have assayed the effects of these peptides on different subtypes of NaV and KV channels expressed in Xenopus oocytes. AcaIII2970 and AcaIII3090 toxins selectively slow down the fast inactivation of rNaV1.3, mNaV1.6 and hNaV1.5 subtypes, while the other mammalian isoforms remained unaffected. Importantly, AcaIII2970 and AcaIII3090 were also examined in insect DmNaV1 channel, revealing a clear phyla-selectivity with regards to the efficacy of the toxin. AcaIII2970 and AcaIII3090 strongly inhibit the inactivation of the insect NaV channel, resulting in an increase in the amplitude of the peak current, and complete removal of the fast and steady-state inactivation. In order to quantify this \"phyla-selectivity\", curves of the concentration dependence of the delayed inactivation induced by AcaIII2970 and AcaIII3090 toxins channels with higher efficacy, were built. After plotting the data on a sigmoidal curve the IC50 values were obtained. For AcaIII2970, the following IC50 values were obtained: DmNaV1 = 162.19 ± 11.22 nM, mNaV1.6 = 645.92 ± 18.52 nM and rNaV1.3 = 572.56 ± 44.96 nM. For AcaIII3090, the following IC50 values were obtained: DmNaV1 = 99.03 ± 9.25 nM, mNaV1.6 = 158.30 ± 33.86 nM and rNaV1.3 = 371.60 ± 6.48 nM. AcaIII1425 acts, selectively, blocking rKV1.1, rKV1.6 and rKV4.3 subtypes, while the others isoforms tested remained unaltered. Due the higher specificity of AcaIII1425 to rKV1.1 and rKV1.6 subtypes, assays were performed to evaluate the blocking channel current versus toxin concentration (dose-response curve). IC50 values for the subtypes rKV1.6 and rKV1.1 are 7642.98 ± 1601.65 nM and 241.65 ± 4.27 nM, respectively. Thus, AcaIII1425 is about 32 times more potent in the rKV1.6 than in the rKV1.1 channel. The primary structure of the toxins was determined by the Edman degradation. The partial sequence of AcaIII2970 and AcaIII3090 revealed that these toxins are similar to the type 1 sodium channel sea anemones neurotoxins. The complete sequence of AcaIII1425 has no similarity with other sea anemone toxins, but is similar to the Conus and spider neurotoxins which have a structural motif known as ICK. Thus, we propose that AcaIII1425 comprises a new group of sea anemones toxins that block KV channels. Given the unprecedented nature of the toxin AcaIII1425, in silico assays were carried out in order to further refining the proposed mechanism underlying the interaction between the toxin and the rKV1.6 channel. The results indicate that, in agreement to what has been proposed elsewhere, different regions of the KV channels are important for the toxin selectivity and potency

Anêmonas do mar

Anthopleura cascaia

Anthopleura cascaia

Canais iônicos voltagem-dependentes

Neurotoxinas

Neurotoxins

Peçonha

Sea anemones

Venom

Voltage-gated ion channels

Purificação e caracterização da fração neurotóxica da peçonha da anêmona do mar Anthopleura cascaia / Purification and characterization of the neurotoxic fraction from the venom of the sea anemone Anthopleura cascaia

Bruno Madio

14 June 2012

A peçonha de anêmonas do mar é uma fonte conhecida de compostos bioativos, incluindo peptídeos, que atuam em canais voltagem-dependentes. Foram descritos 4 tipos de neurotoxinas de anêmonas do mar, que atuam em canais NaV e 4 tipos que atuam em canais KV. Essas toxinas têm permitido discriminar subtipos de canais voltagem-dependentes, estreitamente relacionados, e constituem poderosas ferramentas para estudar o funcionamento e estrutura desses canais. Neste estudo, foram isolados e caracterizados três peptídeos da fração neurotóxica da anêmona do mar Anthopleura cascaia. Esses peptídeos foram nomeados como AcaIII1425, AcaIII2970 e AcaIII3090, onde Aca faz referência a espécie e os números seguem os resultados obtidos nas etapas de purificação. A peçonha foi extraída por meio de estímulos elétricos e purificada por gel-filtração (Sephadex G-50) e fase reversa por HPLC (C-18). As massas moleculares foram obtidas por meio de MALDI-TOF, apresentando 3337,4 Da para a AcaIII1425, 4881,7 Da para a AcaIII2970 e 4880,5 Da para AcaIII3090. Através da técnica de voltage-clamp, esses peptídeos foram testados em diferentes subtipos de canais NaV e KV expressados em ovócito de Xenopus. As toxinas AcaIII2970 e AcaIII3090 retardam, de maneira seletiva, a inativação rápida dos subtipos rNaV1.3, mNaV1.6 e hNaV1.5, enquanto que as outras isoformas testadas permaneceram inalteradas. É importantemente salientar que, a AcaIII2970 e AcaIII3090 também foram examinadas no canal de inseto DmNaV1, revelando uma clara \"filo-seletividade\" na eficácia da atividade das toxinas. A AcaIII2970 e AcaIII3090 inibem fortemente a inativação do canal NaV de inseto, resultando em um aumento na amplitude do pico da corrente e removendo completamente a inativação rápida. Para quantificarmos essa \"filo-seletividade\", foram construídas curvas da dependência da concentração no retardo da inativação induzida pelas toxinas AcaIII2970 e AcaIII3090 nos canais em que apresentaram maior eficácia. Os IC50 foram obtidos após a plotagem dos dados em uma curva sigmoidal. Para a AcaIII2970, os seguintes valores de IC50 foram obtidos: DmNaV1 = 162,19 ± 11,22 nM, mNaV1.6 = 645,92 ± 18,52 nM, rNaV1.3 = 572,56 ± 44,96 nM. Para a AcaIII3090, os seguintes valores de IC50 foram obtidos: DmNaV1 = 99,03 ± 9,25 nM, mNaV1.6 = 158,30 ± 33,86 nM, rNaV1.3 = 371,60 ± 6,48 nM. A AcaIII1425 atua, bloqueando, de modo seletivo os subtipos rKV1.1, rKV1.6 e rKV4.3, enquanto que as outras isoformas testadas permaneceram inalteradas. Devido à maior especificidade da toxina AcaIII1425 pelos subtipos rKV1.1 e rKV1.6, foram realizados ensaios de bloqueio da corrente do canal em função da concentração da toxina (curva dose-resposta). Os valores de IC50 para os subtipos rKV1.1 e rKV1.6 são de 7642,98 ±1601,65 nM e 241,65 ±4,27 nM, respectivamente. Desta forma, a AcaIII1425 é cerca de 32 vezes mais potente em canais do subtipo rKV1.6 do que em relação aos canais do subtipo rKV1.1. A estrutura primária das toxinas foram determinadas por degradação de Edman. A sequência parcial da AcaIII2970 e AcaIII3090 revelou que estas são similares a toxinas de canal de sódio do tipo1 de anêmonas do mar. A sequência completa da AcaIII1425 não apresenta similaridade com toxinas de anêmonas do mar, mas é similar a toxinas de Conus e aranha que possuem um motivo estrutural conhecido como ICK. Dessa forma, propomos que a AcaIII1425 seja um novo grupo de toxinas de anêmonas do mar que bloqueiam KV. Dado o ineditismo da toxina AcaIII1425, foram feitos experimentos in silico para obtermos um maior refinamento do mecanismo de interação entre a toxina e o canal rKV1.6. Estes experimentos indicaram que diferentes regiões dos canais KV são importantes para a seletividade e potência da toxina, corroborando com as propostas que vem sendo descritas / The venom of sea anemones is a known source of bioactive compounds, including peptides that act on voltage-gated ion channels. Four types of neurotoxins from sea anemones, acting on NaV channels, and four types acting on KV channels, have been reported. These toxins have developed the ability to discriminate closely related subtypes of voltage-gated channels, making them powerful tools to studying the function and structure of these channels. In this study, we isolated and characterized three peptides of the neurotoxic fraction from the venom of the sea anemone Anthopleura cascaia. These peptides were named as AcaIII1425, and AcaIII2970 AcaIII3090, where Aca refers to the species and the following numbers refer to results obtained in the purification steps. The venom was milked by electric shock and purified by molecular exclusion (Sephadex G-50) and reverse phase HPLC (C-18). Their molecular weights are 3337.4 Da to AcaIII1425, 4881.7 Da to AcaIII2970 and 4880.5 Da to AcaIII3090, obtained through a MALDI-TOF. Using the voltage-clamp technique, we have assayed the effects of these peptides on different subtypes of NaV and KV channels expressed in Xenopus oocytes. AcaIII2970 and AcaIII3090 toxins selectively slow down the fast inactivation of rNaV1.3, mNaV1.6 and hNaV1.5 subtypes, while the other mammalian isoforms remained unaffected. Importantly, AcaIII2970 and AcaIII3090 were also examined in insect DmNaV1 channel, revealing a clear phyla-selectivity with regards to the efficacy of the toxin. AcaIII2970 and AcaIII3090 strongly inhibit the inactivation of the insect NaV channel, resulting in an increase in the amplitude of the peak current, and complete removal of the fast and steady-state inactivation. In order to quantify this \"phyla-selectivity\", curves of the concentration dependence of the delayed inactivation induced by AcaIII2970 and AcaIII3090 toxins channels with higher efficacy, were built. After plotting the data on a sigmoidal curve the IC50 values were obtained. For AcaIII2970, the following IC50 values were obtained: DmNaV1 = 162.19 ± 11.22 nM, mNaV1.6 = 645.92 ± 18.52 nM and rNaV1.3 = 572.56 ± 44.96 nM. For AcaIII3090, the following IC50 values were obtained: DmNaV1 = 99.03 ± 9.25 nM, mNaV1.6 = 158.30 ± 33.86 nM and rNaV1.3 = 371.60 ± 6.48 nM. AcaIII1425 acts, selectively, blocking rKV1.1, rKV1.6 and rKV4.3 subtypes, while the others isoforms tested remained unaltered. Due the higher specificity of AcaIII1425 to rKV1.1 and rKV1.6 subtypes, assays were performed to evaluate the blocking channel current versus toxin concentration (dose-response curve). IC50 values for the subtypes rKV1.6 and rKV1.1 are 7642.98 ± 1601.65 nM and 241.65 ± 4.27 nM, respectively. Thus, AcaIII1425 is about 32 times more potent in the rKV1.6 than in the rKV1.1 channel. The primary structure of the toxins was determined by the Edman degradation. The partial sequence of AcaIII2970 and AcaIII3090 revealed that these toxins are similar to the type 1 sodium channel sea anemones neurotoxins. The complete sequence of AcaIII1425 has no similarity with other sea anemone toxins, but is similar to the Conus and spider neurotoxins which have a structural motif known as ICK. Thus, we propose that AcaIII1425 comprises a new group of sea anemones toxins that block KV channels. Given the unprecedented nature of the toxin AcaIII1425, in silico assays were carried out in order to further refining the proposed mechanism underlying the interaction between the toxin and the rKV1.6 channel. The results indicate that, in agreement to what has been proposed elsewhere, different regions of the KV channels are important for the toxin selectivity and potency

Anêmonas do mar

Anthopleura cascaia

Canais iônicos voltagem-dependentes

Neurotoxinas

Peçonha

Anthopleura cascaia

Neurotoxins

Sea anemones

Venom

Voltage-gated ion channels

Fluorescent Visualization of Cellular Proton Fluxes

Zhang, Lejie

06 September 2018

Proton fluxes through plasma membranes are essential for regulating intracellular and extracellular pH and mediating co-transport of metabolites and ions. Although conventional electrical measurements are highly sensitive and precise for proton current detection, they provide limited specificity and spatial information. My thesis focuses on developing optical approaches to visualize proton fluxes from ion channels and transporters. It has been demonstrated that channel-mediated acid extrusion causes proton depletion at the inner surface of the plasma membrane. Yet, proton dynamics at the extracellular microenvironment are still unclear. In Chapter II, we developed an optical approach to directly measure pH change in this nanodomain by covalently attaching small-molecule, fluorescent proton sensors to the cell’s glycocalyx using glyco-engineering and copper free ‘click’ chemistry. The extracellularly facing sensors enable real-time detection of proton accumulation and depletion at the plasma membrane, providing an indirect readout of channel and transporter activity that correlated with whole-cell proton current. Moreover, the proton wavefront emanating from one cell was readily visible as it crossed over nearby cells. The transport of monocarboxylates, such as lactate and pyruvate is critical for energy metabolism and is mainly mediated by proton-coupled monocarboxylate transporters (MCT1-MCT4). Although pH electrodes and intracellular fluorescent pH sensors have been widely used for measuring the transport of proton-coupled MCTs, they are unable to monitor the subcellular activities and may underestimate the transport rate due to cell’s volume and intracellular buffering. In Chapter III, we used the Chapter II approach to visualize proton-coupled transport by MCT1-transfected HEK293T cells and observed proton depletion followed by a recovery upon extracellular perfusion of L-lactate or pyruvate. In addition, we identified a putative MCT, CG11665/Hrm that is essential for autophagy during cell death in Drosophila. The results demonstrate that Hrm is a bona fide proton-coupled monocarboxylate transporter that transports pyruvate faster than lactate. Although the approach developed in Chapter II enables visualization of proton fluxes from ion channels and transporters, it’s not applicable in some cell types which cannot incorporate unnatural sialic acid precursors into their glycocalyx, such as INS-1 cells and cardiomyocytes. To address this, in Chapter IV we developed a pH-sensitive, fluorescent WGA conjugate, WGA-pHRho that binds to endogenous glycocalyx. Compared to the results in Chapter II and III, cell surface-attached WGA-pHRho has similar fluorescent signals in response to proton fluxes from proton channel Hv1, omega mutant Shaker-IR R362H and MCT1. With WGA-pHRho, we were able to label the plasma membrane of INS-cells and cardiomyocytes and visualized the transport activity of MCT1 in these cells. Taken together, these findings provide news insights into proton dynamics at the extracellular environment and provide new optical tools to visualize proton fluxes from ion channels and transporters. Moreover, the modularity of the approaches makes them adaptable to study any transport events at the plasma membrane in cells, tissues, and organisms.

voltage-gated ion channels

membrane transporters

pH

glycocalyx

proton-coupled transport

fluorescent sensors

Biophysics

Biotechnology

Molecular Biology

Organic Chemistry

Preparation for Nerve Membrane Potential Readings of a Leech, Laboratory Setup and Dissection Process

Caulfield, Jason Patrick

01 June 2009

A well documented laboratory setup, leech preparation process, and bio-potential data recording process are needed. Repeatability and quality data recordings are essential and thus dictate the requirements of the laboratory setup and processes listed above. Advances in technology have both helped and hindered this development. While very precise equipment is required to record the low voltage bio-potentials, noisy electronic equipment and wires surrounding the work area provide high levels of interference. Proper laboratory setup and data recording processes, however, limit the unwanted interference. Quality data can only be recorded from a properly handled and prepared leech subject. Proper setup and procedures result in quality recordings which lend a clean signal for furthering the understanding of nerve functionality. The electrophysiology lab at California Polytechnic State University in San Luis Obispo is an example of a proven lab setup for high quality signal capture.

leech

action-potential

laboratory

bio-potential

Hodgkin Huxley

axon

nerve

ganglia

neuron

voltage-gated-ion-channels

REGULATION OF HCN CHANNEL FUNCTION BY DIRECT cAMP BINDING AND SINGLET OXYGEN

Idikuda, Vinaykumar

01 January 2018

Hyperpolarization-activated, cyclic-nucleotide gated ion channels (HCN channels) are activated by membrane hyperpolarization and modulated by cyclic nucleotides. HCN channels are important to maintain the resting membrane potential and input resistance in neurons and have important physiological functions in the brain and heart. Four mammalian HCN isoforms, HCN1-4, and the isoform cloned from sea urchin, spHCN, have been extensively studied. Among these, only spHCN channel shows a voltage dependent inactivation. Previous studies have shown that the ligand binding in mHCN2 channel is activity dependent: cAMP binding increases along with channel opening or channels in the open state have higher binding affinity for cAMP. But to date, information pertaining to the ligand binding to an inactivated ion channel or desensitized receptor is lacking. To address this gap, we used fluorescently labelled cAMP analogues in conjunction with patch clamp fluorometry (PCF) to study the ligand binding to the spHCN channel in various conformational states. We show that inactivated spHCN channel shows reduced binding affinity for cAMP, compared to that of the closed or open channel. Parallelly, we noticed significant changes to channel function when a combination of laser and photosensitizer was used to study ligand binding. A reactive oxygen species called singlet oxygen has been confirmed to be the major player in this process. Both photo-dynamically generated and chemically generated singlet oxygen modifies spHCN channel by removing the inactivation. The effect of singlet oxygen on channel can be abolished by the mutation of a key histidine (H462) residue in the ion conducting pore. Taken together, these two projects expanded our understanding about the physicochemical nature of fluorophores from two aspects: (i) the release of photon as a valuable tool to study the conformational dynamics in proteins; (ii) the generation of singlet oxygen as an effective modulator of protein function.

HCN channels

Singlet Oxygen

cAMP

Patch clamp Fluorometry

Ligand binding

Ion Channels

spHCN

Voltage gated Ion channels

Cellular and Molecular Physiology

Neuroscience and Neurobiology

Intracellular Calcium Dynamics In Dendrites Of Hippocampal Neurons Rendered Epileptic And In Processes Of Astrocytes Following Glutamate Pretreatment

Padmashri, R

08 1900

The fundamental attribute of neurons is their cellular electrical excitability, which is based on the expression of a plethora of ligand- and voltage-gated membrane channels that give rise to prominent membrane currents and membrane potential variations that represent the biophysical substrate underlying the transfer and integration of information at the cellular level. Dendrites have both an electrical and a biochemical character, which are closely linked. In contrast, glial cells are non-electrically excitable but nevertheless display a form of excitability that is based on variations of the Ca2+ concentration in the cytosol rather than electrical changes in the membrane. Cytoplasmic Ca2+ serves as an intracellular signal that is responsible for controlling a multitude of cellular processes. The key to this pleiotropic role is the complex spatiotemporal organization of the [Ca2+]i rise evoked by extracellular agonists, which allows selected effectors to be recruited and specific actions to be initiated. Ca2+ handling in the cell is maintained by operation of multiple mechanisms of Ca2+ influx, internal release, diffusion, buffering and extrusion. Ca2+ tends to be a rather parochial operator with a small radius of action from its point of entry at the cytoplasm resulting in the concept of microdomains. Dendritic Ca2+ signaling have been shown to be highly compartmentalized and astrocytic processes have been reported to be constituted by hundreds of microdomains that represent the elementary units of the astrocyte Ca2+ signal, from where it can eventually propagate to other regions of the cell. The astrocyte Ca2+ elevation may thus act as intra and intercellular signal that can propagate within and between astrocytes, signaling to different regions of the cell and to different cells. The spatio-temporal features of neuron-to-astrocyte communication, results from diverse neurotransmitters and signaling pathways that converge and cooperate to shape the Ca2+ signal in astrocytes. Alterations in Ca2+ homeostasis have been shown to be associated with major pathological conditions of the brain such as epilepsy, ischemia and neurodegenerative diseases. Although there are evidences of Ca2+ rise in hippocampal neurons in in vitro models of epilepsy (Pal et al., 1999; Limbrick et al., 2001), there is no information on the Ca2+ regulatory mechanisms operating in discrete compartments of the epileptic neuron following Ca2+ influx through voltage gated calcium channels (VGCCs). In the first part of the work, the spatial and temporal profiles of depolarization induced changes in the intracellular Ca2+ concentration in the dendrites of cultured autaptic hippocampal pyramidal neurons rendered epileptic experimentally have been addressed. Our in vitro epilepsy model consisted of hippocampal neurons in autaptic culture that were grown in the presence of kynurenate and high Mg2+, and subsequently washing the preparation free of the blockers. To understand the differences in Ca2+ handling mechanisms in different compartments of a control neuron and the kynurenate treated neuron, a combination of whole-cell patch-clamp recording and fast Ca2+ imaging methods using the Ca2+ indicator Oregon Green 488 BAPTA-1 was applied. All our analysis was focused on localized regions in the dendrite that showed pronounced Ca2+ transients upon activation of high voltage activated (HVA) Ca2+ channels. The spatial extent of Ca2+ signals suggested the presence of distinct dendritic compartments that respond to the depolarizing stimulus. Further, the local Ca2+ transients were observed even in the presence of NMDA and AMPA receptor antagonists, suggesting that the opening of VGCCs primarily triggered the local Ca2+ changes. The prominent changes in intracellular Ca2+ observed in these dendritic regions appear to be sites where Ca2+ evoked dendritic exocytosis (CEDE) takes place. Since cellular Ca2+ buffers determine the amplitude and diffusional spread of neuronal Ca2+ signals, quantitative estimates of the time-dependent spread of intracellular Ca2+ in the dendritic compartments in the control and treated neurons were done using image processing techniques. Physiological changes in Ca2+ channel functioning were also induced by kynurenate treatment and one such noticeable difference was the observation of Ca2+ dependent inactivation in the treated neurons. We provide evidences of localized Ca2+ changes in the dendrites of hippocampal neurons that are rendered epileptic by kynurenate treatment, suggesting that these sites are more vulnerable (Padmashri et al., 2006). This might contribute to the epileptiform activity by local changes in cellular and membrane properties in complex ways that remains to be clearly understood. Status Epilepticus (SE), stroke and traumatic brain injury are all associated with large increases in extracellular glutamate concentrations. The concentration of glutamate in the extracellular fluid is around 3-4 µM and astrocytes are primarily responsible for the uptake of glutamate at the synapses. The extracellular levels of glutamate has been shown to increase dramatically (16 fold) in human SE suggesting an important role of glutamate in the mechanism of seizure activity and seizure related brain damage (Carlson et al., 1992). Several other studies have also shown a persistent increase in extracellular glutamate concentration to potentially neurotoxic concentrations in the epileptogenic hippocampus (During and Spencer, 1993; Sherwin, 1999; Cavus et al., 2005). We addressed the problem related to the effects of prolonged glutamate pretreatment on Ca2+ signaling in an individual astrocyte and its adjoining astrocyte (astrocyte pair), rather than on a syncytium of astrocytes in culture. Individual astrocytes may have functional domains that respond to an agonist through distinct receptor signaling systems. These are difficult to observe in studies that are done on glial syncytium because of spatial limits of image capture. This was examined with simultaneous somatic patch-pipette recording of a single astrocyte to evoke voltage-gated calcium currents, and Ca2+ imaging using the Ca2+ indicator Oregon Green 488 BAPTA-1 to identify the Ca2+ microdomains. Transient Ca2+ changes locked to the depolarization were observed in certain compartments in the astrocyte processes of the depolarized astrocyte and the responses were more pronounced in the adjoining astrocyte of the astrocyte pair. The Ca2+ transient amplitudes were enhanced on pretreatment of cells with glutamate (500 µM for 20 minutes). Estimation of local Ca2+ diffusion coefficients in the astrocytic processes indicated higher values in the adjoining astrocyte of the glutamate pretreated group. In order to understand the underlying mechanisms, we performed the experiments in the presence of different blockers for the metabotropic glutamate receptor, inositol 1,4,5 triphosphate (IP3) receptors and gap junctions. Ca2+ transients recorded on pretreatment of cells with glutamate showed attenuated responses in the presence of the metabotropic glutamate receptor (mGluR) antagonist α-Methyl(4-Carboxy-Phenyl) Glycine (MCPG). Intracellular heparin (an antagonist of IP3 receptor) introduced in the depolarized astrocyte did not affect the Ca2+ transients in the heparin loaded astrocyte, but attenuated the [Ca2+]i responses in the adjoining astrocyte suggesting that IP3 may be the transfer signal. The uncoupling agent 1-Octanol attenuated the [Ca2+]i responses in the adjoining cell of the astrocyte pair in both the control and glutamate pretreated astrocytes indicating the role of gap junctional communication. The findings of [Ca2+]i responses within discrete regions of astrocytic processes suggest that astrocytes may be comprised of microdomains whose properties are altered by glutamate pretreatment. The data also indicates that glutamate induced alterations in Ca2+ signaling in the astrocyte pair may be mediated through phospholipase C (PLC), IP3, internal Ca2+ stores, VGCCs and gap junction channels (Padmashri and Sikdar, 2006). Neuronal (EAAC-1) and glial (GLT-1 and GLAST) glutamate transporters facilitate glutamate reuptake after synaptic release. Transgenic mice with GLT-1 knockout display spontaneous epileptic activity (Tanaka et al., 1997) and loss of glial glutamate transporters using chronic antisense nucleotide administration was reported to result in elevated extracellular glutamate levels and neurodegeneration characteristic of excitotoxity (Rothstein et al., 1996). Dysfunction of glutamate transporters and the resulting increase of glutamate have been speculated to play an important role in infantile epilepsies (Demarque et al., 2004). We examined the effects of pretreatment with glutamate in the presence of the glutamate transport inhibitor threo-β-hydroxy-aspartate (TBHA) and in Na+-free extracellular medium to understand whether this resulted in any alteration in the astrocytic intracellular Ca2+ dynamics following activation of voltage gated calcium channels. The Ca2+ responses were found to be attenuated in both the cases indicating that the elevated levels of extracellular glutamate due to blockade of glutamate transporters may influence the responses mediated by the astrocytic glutamate receptors. Our studies indicate that the heightened extracellular glutamate concentration is not gliotoxic in our experimental system, although it may have a profound effect on altering the activity of surrounding neurons which was not addressed in the present work. Several studies have indicated that neurons control the level of gap junction mediated communication between astrocytes (Giaume and McCarthy, 1996; Rouach et al, 2000). All our earlier studies were done on process bearing astrocytes that were co-cultured with neurons. We have addressed the question as to whether the spatio-temporal changes in [Ca2+]i in astrocyte pairs differ if the astrocytes are cultured in the absence of neurons. The results indicate that there is indeed a significant reduction in the responses that are evoked in response to the depolarization pulse in the adjoining cell of the astrocyte pair. These experiments demonstrate that neurons in the cocultures may selectively enhance the Ca2+ responses possibly by increasing the coupling between the two cells.

Calcium - Biochemistry

Calcium Ion Signaling

Voltage-gated Ion Channels

Hippocampal Neurons

Astrocytes

Calcium Dynamics

Glutamate

Dendrites

Status Epilepticus (SE)

Astrocyte Pairs

Biochemistry