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Dual Roles for Rhoa/Rho-Kinase in the Regulated Trafficking of a Voltage-Sensitive Potassium ChannelStirling, Lee 13 February 2009 (has links)
Kv1.2 is a member of the Shaker family of voltage-sensitive potassium channels and contributes to regulation of membrane excitability. The electrophysiological activity of Kv1.2 undergoes tyrosine kinase-dependent suppression in a process involving RhoA. We report that RhoA elicits suppression of Kv1.2 ionic current by modulating channel endocytosis. This occurs through two distinct pathways, one clathrin-dependent and the other cholesterol-dependent. Activation of RhoA downstream effectors Rho-kinase (ROCK) or protein kinase N (PKN) via the lysophosphatidic acid (LPA) receptor elicits clathrin-dependent Kv1.2 endocytosis and consequent attenuation of its ionic current. LPA-induced channel endocytosis is blocked by ROCK inhibition , dominant negative PKN, or by clathrin RNAi. In contrast, steady-state endocytosis of Kv1.2 in un-stimulated cells is cholesterol-dependent. Inhibition of basal ROCK with Y27632 or basal PKN with HA1077 increases steady-state surface Kv1.2. The Y27632-induced increase persists in the presence of clathrin RNAi and, in the presence of the sterol-binding agent filipin, does not elicit an additive effect. Temperature block experiments in conjunction with studies that perturb trafficking of newly synthesized proteins from the Golgi demonstrate that basal ROCK affects cholesterol-dependent trafficking by modulating the recycling of constitutively endocytosed Kv1.2 back to the plasma membrane. Both receptor-stimulated and steady-state Kv1.2 trafficking modulated by RhoA/ROCK require the activation of dynamin as well as the ROCK effector LIM kinase, indicating a key role for actin remodeling in RhoA-dependent Kv1.2 regulation.
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Potassium channel expression and function in the N9 murine microglial cell linePan, Geng January 2012 (has links)
Microglia are immunocompetent cells in the central nervous system that have many similarities with macrophages of peripheral tissues. Their activation protects local cells from foreign microbial infection in the CNS. However, “over-activated“ microglia become a “Double-edged sword” which show neuronal toxicity and are implicated in a variety of neurodegenerative diseases. Previous studies have suggested that potassium channels play a role in regulating microglial activation, migration and proliferation. However what kinds of potassium channel subunits are expressed in microglia, whether their expression changes after microglial activation and the functional role of most potassium channels expressed in microglia are still not fully characterized. To address these questions, we used the N9 mouse microglial cell line as a cell model for experiments in vitro. We first optimized the cell culture and lipopolysaccharide (LPS), the endotoxin of gram-negative bacteria, mediated stimulation of microglial activation that results in subsequent nitric oxide (NO) release. Using qRT-PCR, we analyzed mRNA expression of >80 potassium channel pore-forming subunits and their regulatory subunits in both LPS-treated (1μg/ml, 24hr) and untreated microglia. The subunits which displayed the highest mRNA expression in resting N9 cells included Kcnma1 (KCa1.1), Kcnk6 (K2p6.1), Kcnc3 (Kv3.3) and Abcc8 (SUR1). In addition, N9 cells also expressed the mRNAs for other channel subunits previously reported in microglia such as Kcnn4 (KCa3.1), Kcna3 (Kv1.3) and Kcna5 (Kv1.5) subunits. Of these channel subunits LPS had no significant effect on mRNA expression except for Kcnk6 which was significantly reduced. We then examined whether pharmacological manipulation of these channels controlled LPS-induced NO release. It was found out that the KCa3.1 selective blocker Tram34 and the Kv1.5 inhibitor propafenone (PPF) significantly decreased LPS-induced NO in agreement with data in primary microglia. Ba2+ that inhibits inwardly rectifying potassium channels as well as K2p6.1 also significantly attenuated LPS-induced microglial activation. Inhibition or activation of KCa1.1 channels by paxilline and NS1619 respectively had no significant effect. However, paxilline significantly attenuated the effect of Tram34, PPF and Ba2+ to control LPSinduced NO release while NS1619 significantly facilitated the effect of Tram34 and PPF. To investigate the major ionic currents expressed in N9 microglia with and without LPS application, we examined whole-cell ionic currents using the patch-clamp technique. Resting N9 cells display a small outward current at positive potentials but a large inwardly rectifying component at negative potentials in physiological potassium gradients. The outward current was dramatically increased by LPS application that was dependent upon the intracellular free calcium concentration. Paxilline or Tram34 was then applied to acutely block this apparent outward KCa current. The result indicated that the LPS triggered KCa current was mainly paxilline sensitive supporting a role for an LPS-induced increase in KCa1.1 channel current. In addition, by using current clamp the mean resting membrane potential of N9 cells was -50.6±6.6mV (N=7) determined in the presence of 1μM [Ca2+]i and -59.4±8.5mV (N=10) with 10nM [Ca2+]i. N9 cells did not display any spontaneous action potentials and the resting membrane potential was not significantly affected by LPS. To conclude, the work presented in this thesis extends the current knowledge regarding potassium channel mRNA expression in microglia and their function in microglial NO release. What is more, it was found that KCa1.1 current expression was increased in LPS-activated N9 cells and revealed KCa1.1 channels as a modulator of NO release by activated microglia.
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Positive Trafficking Pathways of a Voltage Gated Potassium ChannelConnors, Emilee 02 October 2009 (has links)
ABSTRACT The voltage-gated potassium channel Kv1.2 is a key determinant of cellular excitability in the nervous and cardiovascular systems. In the brain, Kv1.2 is strongly expressed in neurons of the hippocampus, a structure essential for learning and memory, and the cerebellum, a structure essential for motor control and cognition. In the vasculature, Kv1.2 is expressed in smooth muscle cells where it contributes to the regulation of blood flow. Dynamic regulation of Kv1.2 is fundamental to its role in these tissues. Disruption of this regulation can manifest in a range of pathological conditions, including seizure, hypertension and neuropathic pain. Thus, elucidating the mechanisms by which Kv1.2 is regulated addresses fundamental aspects of human physiology and disease. Kv1.2 was the first voltage gated ion channel found to be regulated by tyrosine phosphorylation. The ionic current of Kv1.2 is suppressed following tyrosine phosphorylation by a process involving channel endocytosis. Movement of channel away from the plasma membrane involves many proteins associated with the cytoskeleton, including dynamin, cortactin and RhoA. Because trafficking of Kv1.2 away from the cell surface has emerged as the primary mechanism for its negative regulation, we hypothesized that trafficking of the channel to the cell surface could be a mechanism for positive regulation of the Kv1.2 ionic current. Activation of the cAMP/PKA pathway enhances the ionic current of Kv1.2. We hypothesized that a mechanism for this positive regulation is an increase in the amount of channel protein present at the cell surface. Our data show that cAMP can regulate Kv1.2 surface levels by two opposing trafficking pathways, one PKA-dependent and one PKA-independent. Channel homeostasis is preserved by the dynamic balance between these two pathways. Accordingly, any change in the levels of cAMP causes a net increase in the amount of Kv1.2 present at the cell surface. Specific C-terminal phosphorylation sites of Kv1.2 were identified and shown to have a role in maintaining basal surface channel levels. These findings demonstrate channel trafficking as a mechanism for the positive regulation of the Kv1.2 ionic current. In addition to Kv1.2 trafficking at the plasma membrane, movement of the channel from the biosynthetic pathway to the cell surface is another checkpoint for its regulation. Here we show that the protein arginine methyltransferase 8 (PRMT8) is able to promote the ER exit of Kv1.2, resulting in an increase in Kv1.2 surface expression. PRMT8 not only promoted surface expression of the high mannose glycosylated form of Kv1.2, characteristic of immature, ER-localized channels, but also enhanced Kv1.2 total protein levels, most likely by decreasing the amount of channel protein available for ER-associated degradation (ERAD). These findings highlight biosynthetic trafficking of Kv1.2 as a crucial part of its regulation and identify a novel role for PRMT8, as a regulator of biosynthetic protein trafficking.
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Structural examination of voltage gated potassium channels by voltage clamp fluorometryVaid, Moninder 05 1900 (has links)
Voltage clamp fluorometry (VCF) was first developed in the mid 1990s by Isacoff and his colleagues. In this approach fluorophores are attached to substituted cysteine residues that are engineered by site-directed mutagenesis. Changes in the dielectric environment of the fluorophore report local transitions that are associated with electrically-related and electrically-silent transitions. VCF provides a powerful technique to observe real time reports of ion channel gating conformations. It has proven to be a useful technique because it adds insight that is not available using other techniques. X-ray crystallography studies give a predominantly static picture of the channel, while patch clamping of channels gives information only about residues that effect ionic current flow. Similarly, gating current provides insight only about residues that are charged and move across the membrane electric field.
In this thesis we examined the structural rearrangements of the Shaker channel and the effect of 4-AP on channel gating. We also examined for the first time the structural rearrangements of the Kv1.5 gating and the how the channel responds to depolarization pulses. This work is instrumental in the examination of the potassium channel gating.
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Structural examination of voltage gated potassium channels by voltage clamp fluorometryVaid, Moninder 05 1900 (has links)
Voltage clamp fluorometry (VCF) was first developed in the mid 1990s by Isacoff and his colleagues. In this approach fluorophores are attached to substituted cysteine residues that are engineered by site-directed mutagenesis. Changes in the dielectric environment of the fluorophore report local transitions that are associated with electrically-related and electrically-silent transitions. VCF provides a powerful technique to observe real time reports of ion channel gating conformations. It has proven to be a useful technique because it adds insight that is not available using other techniques. X-ray crystallography studies give a predominantly static picture of the channel, while patch clamping of channels gives information only about residues that effect ionic current flow. Similarly, gating current provides insight only about residues that are charged and move across the membrane electric field.
In this thesis we examined the structural rearrangements of the Shaker channel and the effect of 4-AP on channel gating. We also examined for the first time the structural rearrangements of the Kv1.5 gating and the how the channel responds to depolarization pulses. This work is instrumental in the examination of the potassium channel gating.
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Structural examination of voltage gated potassium channels by voltage clamp fluorometryVaid, Moninder 05 1900 (has links)
Voltage clamp fluorometry (VCF) was first developed in the mid 1990s by Isacoff and his colleagues. In this approach fluorophores are attached to substituted cysteine residues that are engineered by site-directed mutagenesis. Changes in the dielectric environment of the fluorophore report local transitions that are associated with electrically-related and electrically-silent transitions. VCF provides a powerful technique to observe real time reports of ion channel gating conformations. It has proven to be a useful technique because it adds insight that is not available using other techniques. X-ray crystallography studies give a predominantly static picture of the channel, while patch clamping of channels gives information only about residues that effect ionic current flow. Similarly, gating current provides insight only about residues that are charged and move across the membrane electric field.
In this thesis we examined the structural rearrangements of the Shaker channel and the effect of 4-AP on channel gating. We also examined for the first time the structural rearrangements of the Kv1.5 gating and the how the channel responds to depolarization pulses. This work is instrumental in the examination of the potassium channel gating. / Medicine, Faculty of / Cellular and Physiological Sciences, Department of / Graduate
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Mutations on EF-hands of potassium channel-interacting protein2.2 affect its interaction with Kv channelLee, Li-ya 28 July 2006 (has links)
Mutagenesis studies on the four EF-hands of KChIP2.2 (Potassium channel-interacting protein 2.2) were carried out to explore the conformational transition upon the binding of Ca2+ and Mg2+ and the subsequent effect on the interaction between KChIP2.2 and Kv4.2. CD spectra indicated that Ca2+- and Mg2+-loaded wild-type and mutated KChIP2.2 altered the secondary structure contents. In contrast to other mutants, mutation on EF1 caused a notably change in the secondary structure of KChIP2.2. Fluorescence measurement revealed that EF-hands 3 and 4 were high affinity Ca2+-binding sites within KChIP2.2 molecule, but the binding of Mg2+ with KChIP2.2 was marginally affected by EF-hand mutations. The results of size-exclusion chromatography showed that mutations on EF-1, EF-2 and EF-3 induced the oligomerization of KChIP2.2 and the extent of oligomerization was enhanced by Ca2+ and Mg2+. No significant differences were noted when wild-type and mutated KChIP2.2 bound with porcine brain membrane and liposome either in the absence or presence of Ca2+- and Mg2+. Pull down assay showed that KChIP2.2 and EF-hand mutants could bind with Kv4.2 in the absence of Ca2+ and Mg2+, but the interaction was enhanced by Ca2+ and Mg2+. However, the binding capability of mutants for Kv4.2 was notably lower than that observed for wild-type KChIP2.2. It was found that, in sharp contrast to that EF1 mutant exclusively localized in the nucleus, the other EF-hand mutants and wild-type protein distributed within nucleus as well as cytoplasm. Elevating intracellular Ca2+ concentration caused the translocation of EF1 mutant to cytoplasm but no appreciable effect on other mutants and wild-type KChIP2.2. . Taken together, these results suggest that the integrity of the four EF-hands are involved in function to stabilize conformation for binding with Kv channel, but this conformational transition is not essential for the binding to cell membrane.
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Genes and spike timing : how the Kcna1 gene helps limit action potential temporal variability /Gittelman, Joshua X. January 2005 (has links)
Thesis (Ph. D.)--University of Washington, 2005. / Vita. Includes bibliographical references (leaves 84-89).
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CONTRIBUTIONS OF EAG PROTEIN TO NEURONAL EXCITABILITY IN IDENTIFIED THORACIC MOTONEURONS OF DROSOPHILASrinivasan, Subhashini January 2010 (has links)
Diversity in the expression of ion channel proteins among neurons allows a wide range of excitability, growth and functional regulation. Ether-a-go-go (EAG), a member of the voltage-gated K+ channels, was characterized by spontaneous firing in nerve terminals and enhanced neurotransmitter release. In situ whole-cell patch-clamp recordings performed from the somata of Drosophila larval thoracic aCC motoneurons revealed spontaneous spike-like events in eag mutants. Spontaneous events were absent in wild type motoneurons. Spikes evoked by somatic current injection in to the cell body were not altered and comparable to wild type. Spontaneous spike-like events could be due to increased synaptic drive or altered intrinsic excitability of the motoneuron. Reduction of EAG function with selective expression of eag double stranded RNAi transgene in motoneurons only did not cause spontaneous spike-like events or alter evoked firing. This suggests increased synaptic drive contributes to spontaneous events.Both transient and sustained voltage-activated K+ currents, each with Ca++-sensitive (IA(Ca) and IK(Ca)) and Ca++ -insensitive components (IA and IK), were isolated in thoracic aCC motoneurons. In wild type motoneurons, IA was larger than IA(Ca). Conversely, IK(Ca) was larger than IK. Both eag mutants and eag RNAi expression resulted in a decrease in IA , IK and a slow sustained K+ current. Further, EAG and Shal demonstrate a potential functional interaction and contribute to IA. The voltage sensitivity for inactivation was reduced in Shal only and EAG-Shal double knock down compared to controls and EAG only knock down. In addition, a Ca++ sensitive EAG dependent K+ current was blocked by cAMP. Thus, both voltage-dependent and modulatory functions of EAG influence excitability in motoneurons.Firing properties and K+ currents distinguish aCC motoneurons in thoracic segments, T1 and T3. T3aCC had a shorter delay to spike, higher input resistance and were more easily recruited than T1aCC. T1aCC had a larger IA than T3aCC, but comparable IA(Ca). IK(Ca) was larger in T3aCC compared to T1aCC. These differences reflect cell-specific ion channel distribution that could contribute to patterned segmental motor output.
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Regulation of KCNQ1 potassium channel trafficking and gating by KCNE1 and KCNE3 /Choi, Eun Kyung. January 2009 (has links)
Thesis (Ph. D.)--Cornell University, May, 2009. / Vita. Includes bibliographical references (leaves 163-186).
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