Your search keyword '"Anastasios V Tzingounis"' showing total 56 results

1. The palmitoyl acyltransferase ZDHHC14 controls Kv1-family potassium channel clustering at the axon initial segment

Author

Shaun S Sanders, Luiselys M Hernandez, Heun Soh, Santi Karnam, Randall S Walikonis, Anastasios V Tzingounis, and Gareth M Thomas

Subjects

palmitoylation, PSD93, voltage-gated potassium channels, ZDHHC14, DLG2, Kv1 channels, Medicine, Science, Biology (General), QH301-705.5

Abstract

The palmitoyl acyltransferase (PAT) ZDHHC14 is highly expressed in the hippocampus and is the only PAT predicted to bind Type-I PDZ domain-containing proteins. However, ZDHHC14’s neuronal roles are unknown. Here, we identify the PDZ domain-containing Membrane-associated Guanylate Kinase (MaGUK) PSD93 as a direct ZDHHC14 interactor and substrate. PSD93, but not other MaGUKs, localizes to the axon initial segment (AIS). Using lentiviral-mediated shRNA knockdown in rat hippocampal neurons, we find that ZDHHC14 controls palmitoylation and AIS clustering of PSD93 and also of Kv1 potassium channels, which directly bind PSD93. Neurodevelopmental expression of ZDHHC14 mirrors that of PSD93 and Kv1 channels and, consistent with ZDHHC14’s importance for Kv1 channel clustering, loss of ZDHHC14 decreases outward currents and increases action potential firing in hippocampal neurons. To our knowledge, these findings identify the first neuronal roles and substrates for ZDHHC14 and reveal a previously unappreciated role for palmitoylation in control of neuronal excitability.

Published

2020

2. Modeling of the axon plasma membrane structure and its effects on protein diffusion.

Author

Yihao Zhang, Anastasios V Tzingounis, and George Lykotrafitis

Subjects

Biology (General), QH301-705.5

Abstract

The axon plasma membrane consists of the membrane skeleton, which comprises ring-like actin filaments connected to each other by spectrin tetramers, and the lipid bilayer, which is tethered to the skeleton via, at least, ankyrin. Currently it is unknown whether this unique axon plasma membrane skeleton (APMS) sets the diffusion rules of lipids and proteins in the axon. To answer this question, we developed a coarse-grain molecular dynamics model for the axon that includes the APMS, the phospholipid bilayer, transmembrane proteins (TMPs), and integral monotopic proteins (IMPs) in both the inner and outer lipid layers. We first showed that actin rings limit the longitudinal diffusion of TMPs and the IMPs of the inner leaflet but not of the IMPs of the outer leaflet. To reconcile the experimental observations, which show restricted diffusion of IMPs of the outer leaflet, with our simulations, we conjectured the existence of actin-anchored proteins that form a fence which restricts the longitudinal diffusion of IMPs of the outer leaflet. We also showed that spectrin filaments could modify transverse diffusion of TMPs and IMPs of the inner leaflet, depending on the strength of the association between lipids and spectrin. For instance, in areas where spectrin binds to the lipid bilayer, spectrin filaments would restrict diffusion of proteins within the skeleton corrals. In contrast, in areas where spectrin and lipids are not associated, spectrin modifies the diffusion of TMPs and IMPs of the inner leaflet from normal to confined-hop diffusion. Overall, we showed that diffusion of axon plasma membrane proteins is deeply anisotropic, as longitudinal diffusion is of different type than transverse diffusion. Finally, we investigated how accumulation of TMPs affects diffusion of TMPs and IMPs of both the inner and outer leaflets by changing the density of TMPs. We showed that the APMS structure acts as a fence that restricts the diffusion of TMPs and IMPs of the inner leaflet within the membrane skeleton corrals. Our findings provide insight into how the axon skeleton acts as diffusion barrier and maintains neuronal polarity.

Published

2019

3. Deletion of KCNQ2/3 potassium channels from PV+ interneurons leads to homeostatic potentiation of excitatory transmission

Author

Heun Soh, Suhyeorn Park, Kali Ryan, Kristen Springer, Atul Maheshwari, and Anastasios V Tzingounis

Subjects

potassium channels, KCNQ2, KCNQ3, interneurons, epilepsy, seizure, Medicine, Science, Biology (General), QH301-705.5

Abstract

KCNQ2/3 channels, ubiquitously expressed neuronal potassium channels, have emerged as indispensable regulators of brain network activity. Despite their critical role in brain homeostasis, the mechanisms by which KCNQ2/3 dysfunction lead to hypersychrony are not fully known. Here, we show that deletion of KCNQ2/3 channels changed PV+ interneurons’, but not SST+ interneurons’, firing properties. We also find that deletion of either KCNQ2/3 or KCNQ2 channels from PV+ interneurons led to elevated homeostatic potentiation of fast excitatory transmission in pyramidal neurons. Pvalb-Kcnq2 null-mice showed increased seizure susceptibility, suggesting that decreases in interneuron KCNQ2/3 activity remodels excitatory networks, providing a new function for these channels.

Published

2018

4. Modeling of the axon membrane skeleton structure and implications for its mechanical properties.

Author

Yihao Zhang, Krithika Abiraman, He Li, David M Pierce, Anastasios V Tzingounis, and George Lykotrafitis

Subjects

Biology (General), QH301-705.5

Abstract

Super-resolution microscopy recently revealed that, unlike the soma and dendrites, the axon membrane skeleton is structured as a series of actin rings connected by spectrin filaments that are held under tension. Currently, the structure-function relationship of the axonal structure is unclear. Here, we used atomic force microscopy (AFM) to show that the stiffness of the axon plasma membrane is significantly higher than the stiffnesses of dendrites and somata. To examine whether the structure of the axon plasma membrane determines its overall stiffness, we introduced a coarse-grain molecular dynamics model of the axon membrane skeleton that reproduces the structure identified by super-resolution microscopy. Our proposed computational model accurately simulates the median value of the Young's modulus of the axon plasma membrane determined by atomic force microscopy. It also predicts that because the spectrin filaments are under entropic tension, the thermal random motion of the voltage-gated sodium channels (Nav), which are bound to ankyrin particles, a critical axonal protein, is reduced compared to the thermal motion when spectrin filaments are held at equilibrium. Lastly, our model predicts that because spectrin filaments are under tension, any axonal injuries that lacerate spectrin filaments will likely lead to a permanent disruption of the membrane skeleton due to the inability of spectrin filaments to spontaneously form their initial under-tension configuration.

Published

2017

5. The Calcium-Activated Slow AHP: Cutting Through the Gordian Knot

Author

Rodrigo eAndrade, Robert Charles Foehring, and Anastasios V Tzingounis

Subjects

KCNQ, Neuromodulation, 5)P2, PtdIns(4, Ca2+-activated afterhyperpolarization, sAHP, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The phenomenon known as the slow afterhyperpolarization (sAHP) was originally described more than 30 years ago in pyramidal cells as a slow, Ca2+-dependent afterpotential controlling spike frequency adaptation. Subsequent work showed that similar sAHPs were widely expressed in the brain and were mediated by a Ca2+-activated potassium current that was voltage independent, insensitive to most potassium channel blockers, and strongly modulated by neurotransmitters. However the molecular basis for this current has remained poorly understood. The sAHP was initially imagined to reflect the activation of a potassium channel directly gated by Ca2+ but recent studies have begun to question this idea. The sAHP is distinct from the Ca2+-dependent fast and medium AHPs in that it appears to sense cytoplasmic [Ca2+]i and recent evidence implicates proteins of the neuronal calcium sensor family as diffusible cytoplasmic Ca2+ sensors for the sAHP. Translocation of Ca2+-bound sensor to the plasma membrane would then be an intermediate step between Ca2+ and the sAHP channels. Parallel studies strongly suggest that the sAHP current is carried by different potassium channel types depending on the cell type. Finally, the sAHP current is dependent on membrane PtdIns(4,5)P2 and Ca2+ appears to gate this current by increasing PtdIns(4,5)P2 levels. Because membrane PtdIns(4,5)P2 is essential for the activity of many potassium channels, these finding have led us to hypothesize that the sAHP reflects a transient Ca2+-induced increase in the local availability of PtdIns(4,5)P2 which then activates a variety of potassium channels. If this view is correct, the sAHP current would not represent a unitary ionic current but the embodiment of a generalized potassium channel gating mechanism. This model can potentially explain the cardinal features of the sAHP, including its cellular heterogeneity, slow kinetics, dependence on cytoplasmic [Ca2+], high temperature-dependence, and modulation.

Published

2012

6. Place fields of single spikes in hippocampus involve Kcnq3 channel-dependent entrainment of complex spike bursts

Author

Xiaojie Gao, Franziska Bender, Heun Soh, Changwan Chen, Mahsa Altafi, Sebastian Schütze, Matthias Heidenreich, Maria Gorbati, Mihaela-Anca Corbu, Marta Carus-Cadavieco, Tatiana Korotkova, Anastasios V. Tzingounis, Thomas J. Jentsch, and Alexey Ponomarenko

Subjects

Science

Abstract

Hippocampal pyramidal cells encode an animal’s location by single action potentials and complex spike bursts. The authors show that Kcnq3-containing M-channels synergistically with GABAergic inputs coordinate complex spike bursts during theta oscillations, which is a key mechanism for spatial coding by single spikes.

Published

2021

7. Direct reprogramming of oligodendrocyte precursor cells into GABAergic inhibitory neurons by a single homeodomain transcription factor Dlx2

Author

Linda L. Boshans, Heun Soh, William M. Wood, Timothy M. Nolan, Ion I. Mandoiu, Yuchio Yanagawa, Anastasios V. Tzingounis, and Akiko Nishiyama

Subjects

Medicine, Science

Abstract

Abstract Oligodendrocyte precursor cells (NG2 glia) are uniformly distributed proliferative cells in the mammalian central nervous system and generate myelinating oligodendrocytes throughout life. A subpopulation of OPCs in the neocortex arises from progenitor cells in the embryonic ganglionic eminences that also produce inhibitory neurons. The neuronal fate of some progenitor cells is sealed before birth as they become committed to the oligodendrocyte lineage, marked by sustained expression of the oligodendrocyte transcription factor Olig2, which represses the interneuron transcription factor Dlx2. Here we show that misexpression of Dlx2 alone in postnatal mouse OPCs caused them to switch their fate to GABAergic neurons within 2 days by downregulating Olig2 and upregulating a network of inhibitory neuron transcripts. After two weeks, some OPC-derived neurons generated trains of action potentials and formed clusters of GABAergic synaptic proteins. Our study revealed that the developmental molecular logic can be applied to promote neuronal reprogramming from OPCs.

Published

2021

8. The mammalian nodal action potential: new data bring new perspectives

Author

Geoffrey R. Tanner and Anastasios V. Tzingounis

Subjects

Mammals, Potassium Channels, Tandem Pore Domain, Potassium Channels, Voltage-Gated, Physiology, Potassium, Animals, Humans, Action Potentials, General Medicine, Axons, Membrane Potentials, Education

Abstract

Since its discovery in the mid-20th century, the Hodgkin-Huxley biophysical model of the squid giant axon's (SGA's) neurophysiology has traditionally served as the basis for the teaching of action potential (AP) dynamics in the physiology classroom. This model teaches that leak conductances set membrane resting potential; that fast, inactivating, voltage-gated sodium channels effect the SGA AP upstroke; and that delayed, rectifying, noninactivating voltage-gated potassium channels carry AP repolarization and the early part of the afterhyperpolarization (AHP). This model serves well to introduce students to the fundamental ideas of resting potential establishment and maintenance, as well as basic principles of AP generation and propagation. Furthermore, the Hodgkin-Huxley SGA model represents an excellent and accessible starting point for discussion of the concept of AP threshold and the role of passive electrical properties of the neuron. Additionally, the introduction of the Hodgkin-Huxley model of the SGA AP permits the integration of physiological principles, as instructors ask students to apply previously studied principles of transporter and channel biophysics to the essential physiological phenomenon of electrical signal conduction. However, both some early observations as well as more recent evidence strongly suggest that this seminal invertebrate model of AP dynamics does not appropriately capture the full story for mammalian axons. We review recent evidence that mammalian axonal nodes of Ranvier repolarize largely (though not exclusively) through the activity of leak potassium-ion (K

Published

2022

9. The periodic axon membrane skeleton leads to Na nanodomains but does not impact action potentials

Author

Zhaojie Chai, Anastasios V. Tzingounis, and George Lykotrafitis

Subjects

Sodium, Biophysics, Action Potentials, Spectrin, Voltage-Gated Sodium Channels, Actins, Axons

Abstract

Recent work has established that axons have a periodic skeleton structure comprising of azimuthal actin rings connected via longitudinal spectrin tetramer filaments. This structure endows the axon with structural integrity and mechanical stability. Additionally, voltage-gated sodium channels follow the periodicity of the active-spectrin arrangement, spaced ∼190 nm segments apart. The impact of this periodic arrangement of sodium channels on the generation and propagation of action potentials is unknown. To address this question, we simulated an action potential using the Hodgkin-Huxley formalism in a cylindrical compartment, but instead of using a homogeneous distribution of voltage-gated sodium channels in the membrane, we applied the experimentally determined periodic arrangement. We found that the periodic distribution of voltage-gated sodium channels does not significantly affect the generation or propagation of action potentials but instead leads to large, localized sodium action currents caused by high-density sodium nanodomains. Additionally, our simulations show that the distance between periodic sodium channel strips could control axonal excitability, suggesting a previously underappreciated mechanism to regulate neuronal firing properties. Together, this work provides a critical new insight into the role of the periodic arrangement of sodium channels in axons, providing a foundation for future experimental studies.

Published

2022

10. Differential Control of Small-conductance Calcium-activated Potassium Channel Diffusion by Actin in Different Neuronal Subcompartments

Author

Shiju Gu, Anastasios V Tzingounis, and George Lykotrafitis

Subjects

General Medicine

Abstract

Small-conductance calcium-activated potassium (SK) channels show a ubiquitous distribution on neurons, in both somatodendritic and axonal regions. SK channels are associated with neuronal activity regulating action potential frequency, dendritic excitability, and synaptic plasticity. Although the physiology of SK channels and the mechanisms that control their surface expression levels have been investigated extensively, little is known about what controls SK channel diffusion in the neuronal plasma membrane. This aspect is important, as the diffusion of SK channels at the surface may control their localization and proximity to calcium channels, hence increasing the likelihood of SK channel activation by calcium. In this study, we successfully investigated the diffusion of SK channels labeled with quantum dots on human embryonic kidney cells and dissociated hippocampal neurons by combining a single-particle tracking method with total internal reflection fluorescence microscopy. We observed that actin filaments interfere with SK mobility, decreasing their diffusion coefficient. We also found that during neuronal maturation, SK channel diffusion was gradually inhibited in somatodendritic compartments. Importantly, we observed that axon barriers formed at approximately days in vitro 6 and restricted the diffusion of SK channels on the axon initial segment (AIS). However, after neuron maturation, SK channels on the AIS were strongly immobilized, even after disruption of the actin network, suggesting that crowding may cause this effect. Altogether, our work provides insight into how SK channels diffuse on the neuronal plasma membrane and how actin and membrane crowding impacts SK channel diffusion.

Published

2023

11. Muscarinic signaling regulates voltage‐gated potassium channel KCNQ2 phosphorylation in the nucleus accumbens via protein kinase C for aversive learning

Author

Md. Omar Faruk, Daisuke Tsuboi, Yukie Yamahashi, Yasuhiro Funahashi, You‐Hsin Lin, Rijwan Uddin Ahammad, Emran Hossen, Mutsuki Amano, Tomoki Nishioka, Anastasios V Tzingounis, Kiyofumi Yamada, Taku Nagai, and Kozo Kaibuchi

Subjects

Male, Mice, Knockout, Receptor, Muscarinic M2, Nerve Tissue Proteins, Muscarinic Antagonists, Muscarinic Agonists, Receptors, Muscarinic, Biochemistry, Nucleus Accumbens, Mice, Inbred C57BL, Mice, Cellular and Molecular Neuroscience, Parasympathetic Nervous System, Avoidance Learning, Animals, KCNQ2 Potassium Channel, Carbachol, Donepezil, Cholinesterase Inhibitors, Phosphorylation, Protein Kinase C

Abstract

The nucleus accumbens (NAc) plays critical roles in emotional behaviors, including aversive learning. Aversive stimuli such as an electric foot shock increase acetylcholine (ACh) in the NAc, and muscarinic signaling appears to increase neuronal excitability and aversive learning. Muscarinic signaling inhibits the voltage-dependent potassium KCNQ current which regulates neuronal excitability, but the regulatory mechanism has not been fully elucidated. Phosphorylation of KCNQ2 at threonine 217 (T217) and its inhibitory effect on channel activity were predicted. However, whether and how muscarinic signaling phosphorylates KCNQ2 in vivo remains unclear. Here, we found that PKC directly phosphorylated KCNQ2 at T217 in vitro. Carbachol and a muscarinic M1 receptor (M1R) agonist facilitated KCNQ2 phosphorylation at T217 in NAc/striatum slices in a PKC-dependent manner. Systemic administration of the cholinesterase inhibitor donepezil, which is commonly used to treat dementia, and electric foot shock to mice induced the phosphorylation of KCNQ2 at T217 in the NAc, whereas phosphorylation was suppressed by an M1R antagonist. Conditional deletion of Kcnq2 in the NAc enhanced electric foot shock induced aversive learning. Our findings indicate that muscarinic signaling induces the phosphorylation of KCNQ2 at T217 via PKC activation for aversive learning.

Published

2021

12. Flexible Stoichiometry: Implications for KCNQ2- and KCNQ3-Associated Neurodevelopmental Disorders

Author

Anastasios V. Tzingounis, Kristen Springer, and Nissi Varghese

Subjects

Nervous system, Cell type, Epilepsy, Disease, Gating, Biology, medicine.disease, Article, Epilepsy, Benign Neonatal, Potassium channel, KCNQ3 Potassium Channel, medicine.anatomical_structure, Developmental Neuroscience, Neurology, Neurodevelopmental Disorders, medicine, Humans, KCNQ2 Potassium Channel, Benign familial neonatal seizures, Age of onset, Neuroscience

Abstract

KCNQ2 and KCNQ3 pathogenic channel variants have been associated with a spectrum of developmentally regulated diseases that vary in age of onset, severity, and whether it is transient (i.e., benign familial neonatal seizures) or long-lasting (i.e., developmental and epileptic encephalopathy). KCNQ2 and KCNQ3 channels have also emerged as a target for novel antiepileptic drugs as their activation could reduce epileptic activity. Consequently, a great effort has taken place over the last 2 decades to understand the mechanisms that control the assembly, gating, and modulation of KCNQ2 and KCNQ3 channels. The current view that KCNQ2 and KCNQ3 channels assemble as heteromeric channels (KCNQ2/3) forms the basis of our understanding of KCNQ2 and KCNQ3 channelopathies and drug design. Here, we review the evidence that supports the formation of KCNQ2/3 heteromers in neurons. We also highlight functional and transcriptomic studies that suggest channel composition might not be necessarily fixed in the nervous system, but rather is dynamic and flexible, allowing some neurons to express KCNQ2 and KCNQ3 homomers. We propose that to fully understand KCNQ2 and KCNQ3 channelopathies, we need to adopt a more flexible view of KCNQ2 and KCNQ3 channel stoichiometry, which might differ across development, brain regions, cell types, and disease states.

Published

2021

13. KCNQ2 and KCNQ5 form heteromeric channels independent of KCNQ3

Author

Heun Soh, Kristen Springer, Klarita Doci, Jeremy L. Balsbaugh, and Anastasios V. Tzingounis

Subjects

Mice, Multidisciplinary, Phenotype, Genotype, KCNQ Potassium Channels, Animals, Brain, KCNQ2 Potassium Channel, Protein Splicing, Nerve Tissue Proteins, KCNQ3 Potassium Channel

Abstract

KCNQ2 and KCNQ3 channels are associated with multiple neurodevelopmental disorders and are also therapeutic targets for neurological and neuropsychiatric diseases. For more than two decades, it has been thought that most KCNQ channels in the brain are either KCNQ2/3 or KCNQ3/5 heteromers. Here, we investigated the potential heteromeric compositions of KCNQ2-containing channels. We applied split-intein protein trans-splicing to form KCNQ2/5 tandems and coexpressed these with and without KCNQ3. Unexpectedly, we found that KCNQ2/5 tandems form functional channels independent of KCNQ3 in heterologous cells. Using mass spectrometry, we went on to demonstrate that KCNQ2 associates with KCNQ5 in native channels in the brain, even in the absence of KCNQ3. Additionally, our functional heterologous expression data are consistent with the formation of KCNQ2/3/5 heteromers. Thus, the composition of KCNQ channels is more diverse than has been previously recognized, necessitating a re-examination of the genotype/phenotype relationship of KCNQ2 pathogenic variants.

Published

2022

14. The Okur-Chung Neurodevelopmental Syndrome Mutation CK2

Author

Danielle M, Caefer, Nhat Q, Phan, Jennifer C, Liddle, Jeremy L, Balsbaugh, Joseph P, O'Shea, Anastasios V, Tzingounis, and Daniel, Schwartz

Abstract

Okur-Chung Neurodevelopmental Syndrome (OCNDS) is caused by heterozygous mutations to the

Published

2022

15. Dopamine Drives Neuronal Excitability via KCNQ Channel Phosphorylation for Reward Behavior

Author

Daisuke Tsuboi, Takeshi Otsuka, Takushi Shimomura, Md Omar Faruk, Yukie Yamahashi, Mutsuki Amano, Yasuhiro Funahashi, Keisuke Kuroda, Tomoki Nishioka, Kenta Kobayashi, Hiromi Sano, Taku Nagai, Kiyofumi Yamada, Anastasios V. Tzingounis, Atsushi Nambu, Yoshihiro Kubo, Yasuo Kawaguchi, and Kozo Kaibuchi

Subjects

Neurons, History, Polymers and Plastics, Dopamine, Mental Disorders, Receptors, Dopamine D1, Nerve Tissue Proteins, General Biochemistry, Genetics and Molecular Biology, Industrial and Manufacturing Engineering, Mice, Inbred C57BL, Mice, Reward, Animals, KCNQ2 Potassium Channel, Phosphorylation, Business and International Management

Abstract

Dysfunctional dopamine signaling is implicated in various neuropsychological disorders. Previously, we reported that dopamine increases D1 receptor (D1R)-expressing medium spiny neuron (MSN) excitability and firing rates in the nucleus accumbens (NAc) via the PKA/Rap1/ERK pathway to promote reward behavior. Here, the results show that the D1R agonist, SKF81297, inhibits KCNQ-mediated currents and increases D1R-MSN firing rates in murine NAc slices, which is abolished by ERK inhibition. In vitro ERK phosphorylates KCNQ2 at Ser414 and Ser476; in vivo, KCNQ2 is phosphorylated downstream of dopamine signaling in NAc slices. Conditional deletion of Kcnq2 in D1R-MSNs reduces the inhibitory effect of SKF81297 on KCNQ channel activity, while enhancing neuronal excitability and cocaine-induced reward behavior. These effects are restored by wild-type, but not phospho-deficient KCNQ2. Hence, D1R-ERK signaling controls MSN excitability via KCNQ2 phosphorylation to regulate reward behavior, making KCNQ2 a potential therapeutical target for psychiatric diseases with a dysfunctional reward circuit.

Published

2022

16. Removal of KCNQ2 from parvalbumin-expressing interneurons improves anti-seizure efficacy of retigabine

Author

Junzhan Jing, Corrinne Dunbar, Alina Sonesra, Ana Chavez, Suhyeorn Park, Ryan Yang, Heun Soh, Maxwell Lee, Anastasios V. Tzingounis, Edward C. Cooper, Xiaolong Jiang, and Atul Maheshwari

Subjects

Mice, Parvalbumins, Developmental Neuroscience, Neurology, Interneurons, Animals, KCNQ2 Potassium Channel, Nerve Tissue Proteins, Carbamates, Phenylenediamines, Article

Abstract

Anti-seizure drug (ASD) targets are widely expressed in both excitatory and inhibitory neurons. It remains unknown if the action of an ASD upon inhibitory neurons could counteract its beneficial effects on excitatory neurons (or vice versa), thereby reducing the efficacy of the ASD. Here, we examine whether the efficacy of the ASD retigabine (RTG) is altered after removal of the Kv7 potassium channel subunit KCNQ2, one of its drug targets, from parvalbumin-expressing interneurons (PV-INs). Parvalbumin-Cre (PV-Cre) mice were crossed with Kcnq2-floxed (Kcnq2(fl/fl)) mice to conditionally delete Kcnq2 from PV-INs. In these conditional knockout mice (cKO, PV-Kcnq2(fl/fl)), RTG (10 mg/kg, i.p.) significantly delayed the onset of either picrotoxin (PTX, 10 mg/kg, i.p)- or kainic acid (KA, 30mg/kg, i.p.)-induced convulsive seizures compared to vehicle, while RTG was not effective in wild-type littermates (WT). Immunostaining for KCNQ2 and KCNQ3 revealed that both subunits were enriched at axon initial segments (AISs) of hippocampal CA1 PV-INs, and their specific expression was selectively abolished in cKO mice. Accordingly, the M-currents recorded from CA1 PV-INs and their sensitivity to RTG were significantly reduced in cKO mice. While the ability of RTG to suppress CA1 excitatory neurons in hippocampal slices was unchanged in cKO mice, its suppressive effect on the spike activity of CA1 PV-INs was significantly reduced compared with WT mice. In addition, the RTG-induced suppression on intrinsic membrane excitability of PV-INs in WT mice was significantly reduced in cKO mice. These findings suggest that preventing RTG from suppressing PV-INs improves its anticonvulsant effect.

Published

2021

17. Self-sustainable intermittent deep brain stimulator

Author

Esraa Elsanadidy, Islam M. Mosa, Bowen Hou, Tobias Schmid, Maher F. El-Kady, Raihan Sayeed Khan, Andreas Haeberlin, Anastasios V. Tzingounis, and James F. Rusling

Subjects

General Energy, General Engineering, General Physics and Astronomy, General Materials Science, General Chemistry

Published

2022

18. Loss of KCNQ2 or KCNQ3 Leads to Multifocal Time-Varying Activity in the Neonatal Forebrain Ex Vivo

Author

Anastasios V. Tzingounis, Bowen Hou, Nissi Varghese, Heun Soh, and Sabato Santaniello

Subjects

Neuronal Excitability, Neocortex, Biology, Neurotransmission, Hippocampal formation, KCNQ3 Potassium Channel, Epilepsy, Mice, Calcium imaging, channelopathy, medicine, Animals, KCNQ2 Potassium Channel, KCNQ2, Neurons, KCNQ3, General Neuroscience, neurodevelopmental disorders, neurology, General Medicine, medicine.disease, medicine.anatomical_structure, Knockout mouse, Forebrain, Excitatory postsynaptic potential, Neuroscience, Research Article: New Research

Abstract

Early neonatal epileptic encephalopathy represents a group of epilepsies often characterized by refractory seizures, regression in cognitive development, and typically poor prognosis. Dysfunction of KCNQ2 and KCNQ3 channels has emerged as a major cause of neonatal epilepsy. However, our understanding of the cellular mechanisms that may both explain the origins of epilepsy and inform treatment strategies for KCNQ2 and KCNQ3 dysfunction is still lacking. Here, using mesoscale calcium imaging and pharmacology, we demonstrate that in mouse neonatal brain slices, conditional loss of Kcnq2 from forebrain excitatory neurons (Pyr:Kcnq2 mice) or constitutive deletion of Kcnq3 leads to sprawling hyperactivity across the neocortex. Surprisingly, the generation of time-varying hypersynchrony in slices from Pyr:Kcnq2 mice does not require fast synaptic transmission. This is in contrast to control littermates and constitutive Kcnq3 knockout mice where activity is primarily driven by fast synaptic transmission in the neocortex. Unlike in the neocortex, hypersynchronous activity in the hippocampal formation from Kcnq2 conditional and Kcnq3 constitutive knockout mice persists in the presence of synaptic transmission blockers. Thus, we propose that loss of KCNQ2 or KCNQ3 function differentially leads to network hyperactivity across the forebrain in a region- and macro-circuit-specific manner. SIGNIFICANCE STATEMENT Neocortical hypersynchrony is a hallmark of neonatal epilepsy but its cellular mechanisms are unclear. This study shows that hypersynchrony in the neocortex can stem from the loss of KCNQ2 function in excitatory neurons even in the absence of fast synaptic transmission, unlike the hypersynchrony in response to KCNQ3 loss in the neocortex. This points to unique network dysfunctions involving potassium KCNQ2 channels as a mechanism for neonatal epilepsy.

Published

2021

19. Mice That Express a KCNQ2 Channel Gain‐of‐Function Variant (R201C) Exhibit a Blunted Ventilatory Response to CO 2

Author

Anastasios V. Tzingounis, Jaseph Soto-Perez, and Daniel K. Mulkey

Subjects

Channel gain, Chemistry, Genetics, Function (mathematics), Molecular Biology, Biochemistry, Biotechnology, Cell biology

Published

2021

20. Towards Targeted Therapy for Neurodevelopmental Disorders Symposium

Author

Anastasios V. Tzingounis and Ethan M. Goldberg

Subjects

Pediatrics, medicine.medical_specialty, business.industry, Autism Spectrum Disorder, medicine.medical_treatment, medicine.disease, Targeted therapy, Epilepsy, Developmental Neuroscience, Neurology, Neurodevelopmental Disorders, Medicine, Autism, Humans, business

Published

2021

21. The Okur-Chung Neurodevelopmental Syndrome (OCNDS) mutation CK2K198Rleads to a rewiring of kinase specificity

Author

Daniel Schwartz, Caefer Dm, Liddle Jc, O’Shea Jp, Phan Nq, Jeremy L. Balsbaugh, and Anastasios V. Tzingounis

Subjects

chemistry.chemical_compound, Chemistry, Kinase, Mutant, Mutation (genetic algorithm), Wild type, Phosphorylation, Tyrosine phosphorylation, Casein kinase 2, Molecular biology, G alpha subunit

Abstract

Okur-Chung Neurodevelopmental Syndrome (OCNDS) is caused by heterozygous mutations to the CSNK2A1 gene, which encodes the alpha subunit of casein kinase II (CK2). The most frequently occurring mutation is lysine 198 to arginine (K198R). To investigate the impact of this mutation, we first generated a high-resolution phosphorylation motif of CK2WT, including the first characterization of specificity for tyrosine phosphorylation activity. A second high resolution motif representing CK2K198Rsubstrate specificity was also generated. Here we report for the first time the impact of the OCNDS associated CK2K198Rmutation. Contrary to prior speculation, the mutation does not result in a loss of function, but rather shifts the substrate specificity of the kinase. Broadly speaking the mutation leads to 1) a decreased preference for acidic residues in the +1 position, 2) a decreased preference for threonine phosphorylation, 3) an increased preference for tyrosine phosphorylation, and 4) an alteration of the tyrosine phosphorylation specificity motif. To further investigate the result of this mutation we have developed a probability-based scoring method, allowing us to predict shifts in phosphorylation in the K198R mutant relative to the wild type kinase. As an initial step we have applied the methodology to the set of axonally localized ion channels in an effort to uncover potential alterations of the phosphoproteome associated with the OCNDS disease condition.

Published

2021

22. KCNQ3 is the principal target of retigabine in CA1 and subicular excitatory neurons

Author

Maurizio Taglialatela, Anna Lauritano, Anastasios V. Tzingounis, Nissi Varghese, Varghese, Nissi, Lauritano, Anna, Taglialatela, Maurizio, and Tzingounis, Anastasios

Subjects

Male, Patch-Clamp Techniques, Physiology, Action Potentials, Phenylenediamines, KCNQ3 Potassium Channel, Food and drug administration, 03 medical and health sciences, Epilepsy, chemistry.chemical_compound, Mice, 0302 clinical medicine, ezogabine, Medicine, Animals, CA1 Region, Hippocampal, seizures, 030304 developmental biology, Mice, Knockout, KCNQ3, 0303 health sciences, business.industry, General Neuroscience, Retigabine, Pyramidal Cells, retigabine, medicine.disease, Mice, Inbred C57BL, chemistry, nervous system, Excitatory postsynaptic potential, epilepsy, Potassium channel opener, Anticonvulsants, Female, Carbamates, business, Neuroscience, 030217 neurology & neurosurgery, Research Article

Abstract

Retigabine is a first-in-class potassium channel opener approved for patients with epilepsy. Unfortunately, several side effects have limited its use in clinical practice, overshadowing its beneficial effects. Multiple studies have shown that retigabine acts by enhancing the activity of members of the voltage-gated KCNQ (Kv7) potassium channel family, particularly the neuronal KCNQ channels KCNQ2-KCNQ5. However, it is currently unknown whether retigabine’s action in neurons is mediated by all KCNQ neuronal channels or by only a subset. This knowledge is necessary to elucidate retigabine’s mechanism of action in the central nervous system and its adverse effects and to design more effective and selective retigabine analogs. In this study, we show that the action of retigabine in excitatory neurons strongly depends on the presence of KCNQ3 channels. Deletion of Kcnq3 severely limited the ability of retigabine to reduce neuronal excitability in mouse CA1 and subiculum excitatory neurons. In addition, we report that in the absence of KCNQ3 channels, retigabine can enhance CA1 pyramidal neuron activity, leading to a greater number of action potentials and reduced spike frequency adaptation; this finding further supports a key role of KCNQ3 channels in mediating the action of retigabine. Our work provides new insight into the action of retigabine in forebrain neurons, clarifying retigabine’s action in the nervous system. NEW & NOTEWORTHY Retigabine has risen to prominence as a first-in-class potassium channel opener approved by the Food and Drug Administration, with potential for treating multiple neurological disorders. Here, we demonstrate that KCNQ3 channels are the primary target of retigabine in excitatory neurons, as deleting these channels greatly diminishes the effect of retigabine in pyramidal neurons. Our data provide the first indication that retigabine controls neuronal firing properties primarily through KCNQ3 channels.

Published

2021

23. Direct reprogramming of oligodendrocyte precursor cells into GABAergic inhibitory neurons by a single homeodomain transcription factor Dlx2

Author

Heun Soh, William M. Wood, Akiko Nishiyama, Timothy M Nolan, Yuchio Yanagawa, Ion I. Mandoiu, Linda L. Boshans, and Anastasios V. Tzingounis

Subjects

0301 basic medicine, Central Nervous System, Interneuron, Science, Embryonic Development, Biology, Inhibitory postsynaptic potential, Article, OLIG2, 03 medical and health sciences, 0302 clinical medicine, Developmental biology, medicine, Progenitor cell, GABAergic Neurons, Cell Proliferation, Homeodomain Proteins, Oligodendrocyte Precursor Cells, Multidisciplinary, Reprogramming, Oligodendrocyte Transcription Factor 2, Cellular Reprogramming, Embryonic stem cell, Oligodendrocyte, Cell biology, 030104 developmental biology, medicine.anatomical_structure, nervous system, Gene Expression Regulation, Differentiation, Synapses, Medicine, GABAergic, Neuroglia, 030217 neurology & neurosurgery, Neuroscience, Transcription Factors

Abstract

Oligodendrocyte precursor cells (NG2 glia) are uniformly distributed proliferative cells in the mammalian central nervous system and generate myelinating oligodendrocytes throughout life. A subpopulation of OPCs in the neocortex arises from progenitor cells in the embryonic ganglionic eminences that also produce inhibitory neurons. The neuronal fate of some progenitor cells is sealed before birth as they become committed to the oligodendrocyte lineage, marked by sustained expression of the oligodendrocyte transcription factor Olig2, which represses the interneuron transcription factor Dlx2. Here we show that misexpression of Dlx2 alone in postnatal mouse OPCs caused them to switch their fate to GABAergic neurons within 2 days by downregulating Olig2 and upregulating a network of inhibitory neuron transcripts. After two weeks, some OPC-derived neurons generated trains of action potentials and formed clusters of GABAergic synaptic proteins. Our study revealed that the developmental molecular logic can be applied to promote neuronal reprogramming from OPCs.

Published

2021

24. Removal of KCNQ2 from Parvalbumin-expressing Interneurons Improves Anti-Seizure Efficacy of Retigabine

Author

Suhyeorn Park, Edward C. Cooper, Junzhan Jing, Heun Soh, Alina Sonesra, Maxwell Lee, Xiaolong Jiang, Corrinne Dunbar, Anastasios V. Tzingounis, and Atul Maheshwari

Subjects

Kainic acid, medicine.medical_specialty, biology, medicine.medical_treatment, Retigabine, Hippocampal formation, Axon initial segment, chemistry.chemical_compound, Anticonvulsant, Endocrinology, chemistry, Internal medicine, Conditional gene knockout, medicine, biology.protein, Parvalbumin, Picrotoxin

Abstract

Anti-seizure drug (ASD) targets are widely expressed in both excitatory and inhibitory neurons. It remains unknown if the action of an ASD upon inhibitory neurons could counteract its beneficial effects on excitatory neurons (or vice versa), thereby reducing the efficacy of the ASD. Here, we examine whether the efficacy of the ASD retigabine (RTG) is altered after removal of the Kv7 potassium channel subunit KCNQ2, one of its drug targets, from parvalbumin-expressing interneurons (PV-INs). Parvalbumin-Cre (PV-Cre) mice were crossed with Kcnq2-floxed (Kcnq2fl/fl) mice to conditionally delete Kcnq2 from PV-INs. In these conditional knockout mice (cKO, PV-Kcnq2fl/fl), RTG (10 mg/kg, i.p.) significantly delayed the onset of either picrotoxin (PTX, 10 mg/kg, i.p)- or kainic acid (KA, 30mg/kg, i.p.)-induced convulsive seizures compared to vehicle, while RTG was not effective in wild-type littermates (WT). Immunostaining for KCNQ2 and KCNQ3 revealed that both subunits were enriched at axon initial segments (AISs) of hippocampal CA1 PV-INs, and their specific expression was selectively abolished in cKO mice. Accordingly, the M-currents recorded from CA1 PV-INs and their sensitivity to RTG were significantly reduced in cKO mice. While the ability of RTG to suppress CA1 excitatory neurons in hippocampal slices was unchanged in cKO mice, its suppressive effect on the spike activity of CA1 PV-INs was significantly reduced compared with WT mice. In addition, the RTG-induced suppression on intrinsic membrane excitability of PV-INs in WT mice was significantly reduced in cKO mice. These findings suggest that preventing RTG from suppressing PV-INs improves its anticonvulsant effect.Significance StatementOne out of three patients with epilepsy remain resistant to anti-seizure drugs (ASD). Therefore, strategies that can enhance the efficacy of current ASDs or aid in the development of novel ASDs are in high demand. Here we show that by sparing a subset of inhibitory neurons, the ASD retigabine becomes more efficacious. These findings indicate that developing the ASDs that have relatively greater effects on excitatory over inhibitory neurons may be an effective strategy to improve the efficacy of ASDs.

Published

2020

25. Author response: The palmitoyl acyltransferase ZDHHC14 controls Kv1-family potassium channel clustering at the axon initial segment

Author

Heun Soh, Anastasios V. Tzingounis, Shaun S. Sanders, Santi Karnam, Randall S. Walikonis, Luiselys M. Hernandez, and Gareth M. Thomas

Subjects

Chemistry, Palmitoyl acyltransferase, Cluster analysis, Axon initial segment, Potassium channel, Cell biology

Published

2020

26. Potassium Channel Gain of Function in Epilepsy: An Unresolved Paradox

Author

Anastasios V. Tzingounis and Zachary Niday

Subjects

0301 basic medicine, Candidate gene, Potassium Channels, KCNJ10, Article, 03 medical and health sciences, Epilepsy, medicine, Animals, Humans, Exome, partial seizures, biology, business.industry, General Neuroscience, medicine.disease, Potassium channel, 030104 developmental biology, Gain of function, Gain of Function Mutation, Clinical diagnosis, biology.protein, Neurology (clinical), business, Neuroscience

Abstract

Exome and targeted sequencing have revolutionized clinical diagnosis. This has been particularly striking in epilepsy and neurodevelopmental disorders, for which new genes or new variants of preexisting candidate genes are being continuously identified at increasing rates every year. A surprising finding of these efforts is the recognition that gain of function potassium channel variants are actually associated with certain types of epilepsy, such as malignant migrating partial seizures of infancy or early-onset epileptic encephalopathy. This development has been difficult to understand as traditionally potassium channel loss-of-function, not gain-of-function, has been associated with hyperexcitability disorders. In this article, we describe the current state of the field regarding the gain-of-function potassium channel variants associated with epilepsy (KCNA2, KCNB1, KCND2, KCNH1, KCNH5, KCNJ10, KCNMA1, KCNQ2, KCNQ3, and KCNT1) and speculate on the possible cellular mechanisms behind the development of seizures and epilepsy in these patients. Understanding how potassium channel gain-of-function leads to epilepsy will provide new insights into the inner working of neural circuits and aid in developing new therapies.

Published

2018

27. Heterozygous loss of epilepsy gene KCNQ2 alters social, repetitive and exploratory behaviors

Author

Eung Chang Kim, Hee Jung Chung, Justin S. Rhodes, Jiaren Zhang, Anastasios V. Tzingounis, Heun Soh, and Jaimin Patel

Subjects

Male, 0301 basic medicine, Heterozygote, medicine.medical_specialty, social dominance, Nerve Tissue Proteins, Mice, 03 medical and health sciences, Behavioral Neuroscience, Epilepsy, 0302 clinical medicine, Loss of Function Mutation, Internal medicine, excitability, Intellectual disability, Genetics, Animals, KCNQ2 Potassium Channel, Medicine, In patient, Social Behavior, Gene, seizures, Dominance (genetics), KCNQ2, business.industry, social interaction, Original Articles, anxiety, Kv7 channels, medicine.disease, Grooming, Motor coordination, locomotion, Mice, Inbred C57BL, 030104 developmental biology, Endocrinology, Neurology, Exploratory Behavior, epilepsy, Home cage, Autism, Original Article, Female, Stereotyped Behavior, business, 030217 neurology & neurosurgery

Abstract

KCNQ/Kv7 channels conduct voltage‐dependent outward potassium currents that potently decrease neuronal excitability. Heterozygous inherited mutations in their principle subunits Kv7.2/KCNQ2 and Kv7.3/KCNQ3 cause benign familial neonatal epilepsy whereas patients with de novo heterozygous Kv7.2 mutations are associated with early‐onset epileptic encephalopathy and neurodevelopmental disorders characterized by intellectual disability, developmental delay and autism. However, the role of Kv7.2‐containing Kv7 channels in behaviors especially autism‐associated behaviors has not been described. Because pathogenic Kv7.2 mutations in patients are typically heterozygous loss‐of‐function mutations, we investigated the contributions of Kv7.2 to exploratory, social, repetitive and compulsive‐like behaviors by behavioral phenotyping of both male and female KCNQ2 +/− mice that were heterozygous null for the KCNQ2 gene. Compared with their wild‐type littermates, male and female KCNQ2 +/− mice displayed increased locomotor activity in their home cage during the light phase but not the dark phase and showed no difference in motor coordination, suggesting hyperactivity during the inactive light phase. In the dark phase, KCNQ2 +/− group showed enhanced exploratory behaviors, and repetitive grooming but decreased sociability with sex differences in the degree of these behaviors. While male KCNQ2 +/− mice displayed enhanced compulsive‐like behavior and social dominance, female KCNQ2 +/− mice did not. In addition to elevated seizure susceptibility, our findings together indicate that heterozygous loss of Kv7.2 induces behavioral abnormalities including autism‐associated behaviors such as reduced sociability and enhanced repetitive behaviors. Therefore, our study is the first to provide a tangible link between loss‐of‐function Kv7.2 mutations and the behavioral comorbidities of Kv7.2‐associated epilepsy., Heterozygous loss of KCNQ2 reduces sociability and enhances repetitive and exploratory behavior in mice.

Published

2019

28. A short bone biomechanics primer: Background for a lesson on bone viscoelasticity

Author

Geoffrey R. Tanner, John M. Redden, and Anastasios V. Tzingounis

Subjects

Orthodontics, Short bone, medicine.anatomical_structure, medicine, Biomechanics, General Medicine, Primer (cosmetics), Viscoelasticity

Published

2019

29. What do Bone and Silly Putty have in Common?: A Lesson on Bone Viscoelasticity Silly Putty have

Author

Anastasios V. Tzingounis, John M. Redden, and Geoffrey R. Tanner

Subjects

Flubber, Polymer science, General Medicine, Viscoelasticity, Mathematics

Published

2019

30. Modeling of the axon plasma membrane structure and its effects on protein diffusion

Author

Anastasios V. Tzingounis, Yihao Zhang, and George Lykotrafitis

Subjects

Lipid Bilayers, Cell Membranes, Mass diffusivity, Spectrins, Biochemistry, Diffusion, 0302 clinical medicine, Nerve Fibers, Contractile Proteins, Animal Cells, Ankyrin, Spectrin, Biology (General), Lipid bilayer, Cytoskeleton, Phospholipids, chemistry.chemical_classification, Neurons, Mass Diffusivity, 0303 health sciences, Ecology, Physics, Lipids, Transmembrane protein, Actin Cytoskeleton, Chemistry, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, lipids (amino acids, peptides, and proteins), Cellular Structures and Organelles, Cellular Types, Research Article, QH301-705.5, Molecular Dynamics Simulation, 03 medical and health sciences, Cellular and Molecular Neuroscience, Genetics, Animals, Humans, Computer Simulation, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Chemical Physics, Cell Membrane, Membrane structure, Membrane Proteins, Biology and Life Sciences, Proteins, Biological Transport, Cell Biology, Actins, Axons, Cytoskeletal Proteins, Membrane protein, chemistry, Restricted Diffusion, Cellular Neuroscience, Biophysics, 030217 neurology & neurosurgery, Neuroscience

Abstract

The axon plasma membrane consists of the membrane skeleton, which comprises ring-like actin filaments connected to each other by spectrin tetramers, and the lipid bilayer, which is tethered to the skeleton via, at least, ankyrin. Currently it is unknown whether this unique axon plasma membrane skeleton (APMS) sets the diffusion rules of lipids and proteins in the axon. To answer this question, we developed a coarse-grain molecular dynamics model for the axon that includes the APMS, the phospholipid bilayer, transmembrane proteins (TMPs), and integral monotopic proteins (IMPs) in both the inner and outer lipid layers. We first showed that actin rings limit the longitudinal diffusion of TMPs and the IMPs of the inner leaflet but not of the IMPs of the outer leaflet. To reconcile the experimental observations, which show restricted diffusion of IMPs of the outer leaflet, with our simulations, we conjectured the existence of actin-anchored proteins that form a fence which restricts the longitudinal diffusion of IMPs of the outer leaflet. We also showed that spectrin filaments could modify transverse diffusion of TMPs and IMPs of the inner leaflet, depending on the strength of the association between lipids and spectrin. For instance, in areas where spectrin binds to the lipid bilayer, spectrin filaments would restrict diffusion of proteins within the skeleton corrals. In contrast, in areas where spectrin and lipids are not associated, spectrin modifies the diffusion of TMPs and IMPs of the inner leaflet from normal to confined-hop diffusion. Overall, we showed that diffusion of axon plasma membrane proteins is deeply anisotropic, as longitudinal diffusion is of different type than transverse diffusion. Finally, we investigated how accumulation of TMPs affects diffusion of TMPs and IMPs of both the inner and outer leaflets by changing the density of TMPs. We showed that the APMS structure acts as a fence that restricts the diffusion of TMPs and IMPs of the inner leaflet within the membrane skeleton corrals. Our findings provide insight into how the axon skeleton acts as diffusion barrier and maintains neuronal polarity., Author summary The axon plasma membrane skeleton consists of repeated periodic actin ring-like structures along its length connected via spectrin tetramers and anchored to the lipid bilayer at least via ankyrin. However, it is currently unclear whether this structure controls diffusion of lipids and proteins in the axon. Here, we developed a coarse-grain molecular dynamics computational model for the axon plasma membrane that comprises minimal representations for the APMS and the lipid bilayer. In a departure from current models, we found that actin rings limit diffusion of proteins only in the inner membrane leaflet. Then, we showed that actin anchored proteins likely act as “fences” confining diffusion of proteins in the outer leaflet. Our simulations, unexpectedly, also revealed that spectrin filaments could impede transverse diffusion in the inner leaflet of the axon and in some conditions modify diffusion from normal to abnormal. We predicted that diffusion of axon plasma membrane proteins is anisotropic as longitudinal diffusion is of different type than transverse (azimuthal) diffusion. We conclude that the periodic structure of the axon plays a critical role in controlling diffusion of proteins and lipids in the axon plasma membrane.

Published

2018

31. Tonic PKA Activity Regulates SK Channel Nanoclustering and Somatodendritic Distribution

Author

George Lykotrafitis, Megha Sah, Anastasios V. Tzingounis, Randall S. Walikonis, and Krithika Abiraman

Subjects

0301 basic medicine, Patch-Clamp Techniques, Small-Conductance Calcium-Activated Potassium Channels, Apamin, Cell Line, SK channel, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Structural Biology, Cyclic AMP, Animals, Humans, Cyclic adenosine monophosphate, Patch clamp, Molecular Biology, Ion channel, Chemistry, Pyramidal Cells, Brain, Anatomy, Cyclic AMP-Dependent Protein Kinases, Calcium-activated potassium channel, Potassium channel, Rats, Electrophysiology, HEK293 Cells, 030104 developmental biology, Biophysics, Calcium, 030217 neurology & neurosurgery

Abstract

Small-conductance calcium-activated potassium (SK) channels mediate a potassium conductance in the brain and are involved in synaptic plasticity, learning, and memory. SK channels show a distinct subcellular localization that is crucial for their neuronal functions. However, the mechanisms that control this spatial distribution are unknown. We imaged SK channels labeled with fluorophore-tagged apamin and monitored SK channel nanoclustering at the single molecule level by combining atomic force microscopy and toxin (i.e., apamin) pharmacology. Using these two complementary approaches, we found that native SK channel distribution in pyramidal neurons, across the somatodendritic domain, depends on ongoing cyclic adenosine monophosphate (cAMP)-protein kinase A (PKA) levels, strongly limiting SK channel expression at the pyramidal neuron soma. Furthermore, tonic cAMP-PKA levels also controlled whether SK channels were expressed in nanodomains as single entities or as a group of multiple channels. Our study reveals a new level of regulation of SK channels by cAMP-PKA and suggests that ion channel topography and nanoclustering might be under the control of second messenger cascades.

Published

2016

32. The Voltage Activation of Cortical KCNQ Channels Depends on Global PIP2 Levels

Author

Kevin M. Duignan, Heun Soh, Kwang S. Kim, Anastasios V. Tzingounis, and Joanna M. Hawryluk

Subjects

0301 basic medicine, Male, Phosphatidylinositol 4,5-Diphosphate, Biophysics, chemistry.chemical_element, Calcium, Phenylenediamines, KCNQ3 Potassium Channel, Membrane Potentials, 03 medical and health sciences, Kcnq channels, Muscarinic acetylcholine receptor, Hippocalcin, medicine, Animals, Humans, Channels and Transporters, Membrane potential, Cerebral Cortex, Mice, Knockout, Neurons, biology, Chemistry, Pyramidal Cells, HEK 293 cells, Mice, Inbred C57BL, 030104 developmental biology, medicine.anatomical_structure, HEK293 Cells, Biochemistry, Slow afterhyperpolarization, Cerebral cortex, biology.protein, lipids (amino acids, peptides, and proteins), Female, Carbamates, Ion Channel Gating

Abstract

The slow afterhyperpolarization (sAHP) is a calcium-activated potassium conductance with critical roles in multiple physiological processes. Pharmacological and genetic data suggest that KCNQ channels partly mediate the sAHP. However, these channels are not typically open within the observed voltage range of the sAHP. Recent work has shown that the sAHP is gated by increased PIP2 levels, which are generated downstream of calcium binding by neuronal calcium sensors such as hippocalcin. Here, we examined whether changes in PIP2 levels could shift the voltage-activation range of KCNQ channels. In HEK293T cells, expression of the PIP5 kinase PIPKIγ90, which increases global PIP2 levels, shifted the KCNQ voltage activation to within the operating range of the sAHP. Further, the sensitivity of this effect on KCNQ3 channels appeared to be higher than that on KCNQ2. Therefore, we predict that KCNQ3 plays an essential role in maintaining the sAHP under low PIP2 conditions. In support of this notion, we find that sAHP inhibition by muscarinic receptors that increase phosphoinositide turnover in neurons is enhanced in Kcnq3-knockout mice. Likewise, the presence of KCNQ3 is essential for maintaining the sAHP when hippocalcin is ablated, a condition that likely impairs PIP2 generation. Together, our results establish the relationship between PIP2 and the voltage dependence of cortical KCNQ channels (KCNQ2/3, KCNQ3/5, and KCNQ5), and suggest a possible mechanism for the involvement of KCNQ channels in the sAHP.

Published

2016

33. SMITten for KCNQ Channels

Author

Anastasios V. Tzingounis

Subjects

0301 basic medicine, endocrine system diseases, biology, urogenital system, business.industry, Long QT syndrome, Biophysics, Cardiac action potential, Atrial fibrillation, medicine.disease, Potassium channel, Potassium current, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Kcnq channels, biology.protein, Medicine, Repolarization, KvLQT1, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Over the last two decades, members of the KCNQ channel family of potassium channels (KCNQ1–5) have emerged as critical regulators of cardiac and neuronal excitability (1,2). KCNQ1 channels are the molecular determinants of the cardiac slow potassium current, IKS (1), which is partly responsible for the repolarization of the cardiac action potential. Loss-of-function variants of KCNQ1 channels lead to a rare heart condition, long QT syndrome, and gain-of-function variants lead to atrial fibrillation.

Published

2017

34. Author response: Deletion of KCNQ2/3 potassium channels from PV+ interneurons leads to homeostatic potentiation of excitatory transmission

Author

Kali Ryan, Heun Soh, Kristen Springer, Suhyeorn Park, Atul Maheshwari, and Anastasios V. Tzingounis

Subjects

Transmission (telecommunications), Chemistry, Excitatory postsynaptic potential, Long-term potentiation, Neuroscience, Potassium channel, Homeostasis

Published

2018

35. Inhibition of KCNQ2/3 channels by HN38 and XE991 depends on the conformation of the outer vestibule

Author

Fajun Nan, Zhaobing Gao, Lei Wang, Klarita Doci, Anastasios V. Tzingounis, Elizabeth Rodier, and Zachary Niday

Subjects

0301 basic medicine, Pharmacology, Retigabine, Protein subunit, HEK 293 cells, Lysine, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Mechanism of action, chemistry, Vestibule, medicine, Biophysics, Molecular Medicine, Heterologous expression, medicine.symptom, Ion channel

Abstract

Recent studies identified HN38 as a novel KCNQ2 channel inhibitor. However, to date no study has carefully examined HN38 in regards to its mechanism of action or determined whether it inhibits KCNQ2/3 channels. To address these questions, we used heterologous expression of human KCNQ2/3 channels in HEK293T cells. Consistent with previous reports, we found that HN38 almost completely blocked KCNQ2 channel activity. This inhibition was independent of the presence of the KCNQ1-5 auxiliary neuronal subunit beta-secretase 1 (BACE-1). Similar to its parent compound, retigabine, HN38 required the presence of KCNQ2 tryptophan W236 for inhibition. Surprisingly, we found that HN38 maximally inhibited KCNQ2/3 channels, as well as the KCNQ2/3-mediated M-current in CA1 pyramidal neurons, by approximately 40%. This incomplete block of KCNQ2/3 channels by HN38 appears to be partially due to the conformation of the KCNQ2/3 outer vestibule and in particular the outer turret lysine 259 of KCNQ3 channels. We conclude that the KCNQ3 outer vestibule conformation regulates the ability of blockers, like HN38 as well as XE991, to inhibit KCNQ2/3 channels, which should be considered for the design of new KCNQ2/3 channels compounds.

Published

2018

36. Deletion of KCNQ2/3 potassium channels from PV+ interneurons leads to homeostatic potentiation of excitatory transmission

Author

Kali Ryan, Atul Maheshwari, Suhyeorn Park, Heun Soh, Kristen Springer, and Anastasios V. Tzingounis

Subjects

0301 basic medicine, Male, Mouse, Synaptic Transmission, Mice, 0302 clinical medicine, parvalbumin, Homeostasis, Biology (General), KCNQ2, KCNQ3, biology, Chemistry, General Neuroscience, musculoskeletal, neural, and ocular physiology, Pyramidal Cells, Long-term potentiation, General Medicine, potassium channels, Potassium channel, Seizure susceptibility, medicine.anatomical_structure, Excitatory postsynaptic potential, Medicine, Female, Interneuron, QH301-705.5, Science, seizure, Short Report, General Biochemistry, Genetics and Molecular Biology, KCNQ3 Potassium Channel, 03 medical and health sciences, medicine, Potassium Channel Blockers, Animals, KCNQ2 Potassium Channel, General Immunology and Microbiology, interneurons, 030104 developmental biology, Transmission (telecommunications), nervous system, biology.protein, epilepsy, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin, Gene Deletion

Abstract

KCNQ2/3 channels, ubiquitously expressed neuronal potassium channels, have emerged as indispensable regulators of brain network activity. Despite their critical role in brain homeostasis, the mechanisms by which KCNQ2/3 dysfunction lead to hypersychrony are not fully known. Here, we show that deletion of KCNQ2/3 channels changed PV+ interneurons’, but not SST+ interneurons’, firing properties. We also find that deletion of either KCNQ2/3 or KCNQ2 channels from PV+ interneurons led to elevated homeostatic potentiation of fast excitatory transmission in pyramidal neurons. Pvalb-Kcnq2 null-mice showed increased seizure susceptibility, suggesting that decreases in interneuron KCNQ2/3 activity remodels excitatory networks, providing a new function for these channels.

Published

2018

37. HCN channels contribute to serotonergic modulation of ventral surface chemosensitive neurons and respiratory activity

Author

Daniel K. Mulkey, Virginia E. Hawkins, Thiago S. Moreira, Ana C. Takakura, Anastasios V. Tzingounis, and Joanna M. Hawryluk

Subjects

Male, Serotonin, Physiology, Action Potentials, Cesium, Serotonergic, Cellular and Molecular Properties of Neurons, Hyperpolarization-Activated Cyclic Nucleotide-Gated Channels, Potassium Channel Blockers, medicine, Animals, Rats, Wistar, Chemistry, Respiration, General Neuroscience, Chemoreceptor Cells, Potassium channel blocker, Respiratory activity, Rats, Pyrimidines, Respiratory network, Adenylyl Cyclase Inhibitors, Retrotrapezoid nucleus, Neuroscience, Brain Stem, Serotonergic Neurons, medicine.drug

Abstract

Chemosensitive neurons in the retrotrapezoid nucleus (RTN) provide a CO2/H+-dependent drive to breathe and function as an integration center for the respiratory network, including serotonergic raphe neurons. We recently showed that serotonergic modulation of RTN chemoreceptors involved inhibition of KCNQ channels and activation of an unknown inward current. Hyperpolarization-activated cyclic-nucleotide-gated (HCN) channels are the molecular correlate of the hyperpolarization-activated inward current ( Ih) and have a high propensity for modulation by serotonin. To investigate whether HCN channels contribute to basal activity and serotonergic modulation of RTN chemoreceptors, we characterize resting activity and the effects of serotonin on RTN chemoreceptors in vitro and on respiratory activity of anesthetized rats in the presence or absence of blockers of KCNQ (XE991) and/or HCN (ZD7288, Cs+) channels. We found in vivo that bilateral RTN injections of ZD7288 increased respiratory activity and in vitro HCN channel blockade increased activity of RTN chemoreceptors under control conditions, but this was blunted by KCNQ channel inhibition. Furthermore, in vivo unilateral RTN injection of XE991 plus ZD7288 eliminated the serotonin response, and in vitro serotonin sensitivity was eliminated by application of XE991 and ZD7288 or SQ22536 (adenylate cyclase blocker). Serotonin-mediated activation of RTN chemoreceptors was blocked by a 5-HT7-receptor blocker and mimicked by a 5-HT7-receptor agonist. In addition, serotonin caused a depolarizing shift in the voltage-dependent activation of Ih. These results suggest that HCN channels contribute to resting chemoreceptor activity and that serotonin activates RTN chemoreceptors and breathing in part by a 5-HT7receptor-dependent mechanism and downstream activation of Ih.

Published

2015

38. K

Author

Anastasios V. Tzingounis, Krithika Abiraman, and George Lykotrafitis

Subjects

0301 basic medicine, Small-Conductance Calcium-Activated Potassium Channels, Potassium, chemistry.chemical_element, Axon hillock, Endocytosis, Biochemistry, 03 medical and health sciences, Genetics, Cyclic AMP, Animals, Telodendron, Molecular Biology, Cells, Cultured, Research, Cell Membrane, Conductance, Axon initial segment, Cyclic AMP-Dependent Protein Kinases, Potassium channel, Axons, Rats, Protein Transport, 030104 developmental biology, chemistry, Biophysics, Erratum, Biotechnology, Communication channel

Abstract

Small conductance calcium-activated potassium (K(Ca)2) channels are expressed throughout the CNS and play a critical role in synaptic and neuronal excitability. K(Ca)2 channels have a somatodendritic distribution with their highest expression in distal dendrites. It is unclear whether K(Ca)2 channels are specifically present on the axon initial segment (AIS), the site at which action potentials are initiated in neurons. Through a powerful combination of toxin pharmacology, single-molecule atomic force microscopy, and dual-color fluorescence microscopy, we report here that K(Ca)2 channels—predominantly the K(Ca)2.3 subtype—are indeed present on the AIS. We also report that cAMP-PKA controls the axonal K(Ca)2 channel surface expression. Surprisingly, and in contrast to K(Ca)2 channels that were observed in the soma and dendrites, the inhibition of cAMP-PKA increased the surface expression of K(Ca)2 channels without promoting nanoclustering. Lastly, we found that axonal K(Ca)2 channels seem to undergo endocytosis in a dynamin-independent manner, unlike K(Ca)2 channels in the soma and dendrites. Together, these novel results demonstrate that the distribution and membrane recycling of K(Ca)2 channels differs among various neuronal subcompartments.—Abiraman, K., Tzingounis, A. V., Lykotrafitis, G. K(Ca)2 channel localization and regulation in the axon initial segment.

Published

2017

39. Modeling of the axon membrane skeleton structure and implications for its mechanical properties

Author

George Lykotrafitis, Krithika Abiraman, He Li, David M. Pierce, Yihao Zhang, and Anastasios V. Tzingounis

Subjects

0301 basic medicine, Physiology, Cell Membranes, Spectrins, Actin Filaments, Microscopy, Atomic Force, Biochemistry, Stiffness, 0302 clinical medicine, Nerve Fibers, Animal Cells, Medicine and Health Sciences, Ankyrin, Spectrin, Biology (General), Axon, Cells, Cultured, Membrane potential, chemistry.chemical_classification, Neurons, Ecology, Chemistry, Anatomy, Electrophysiology, Cell Motility, Membrane, medicine.anatomical_structure, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Cellular Types, Cellular Structures and Organelles, Research Article, Ankyrins, QH301-705.5, Materials Science, Material Properties, Finite Element Analysis, macromolecular substances, Membrane Potential, Models, Biological, 03 medical and health sciences, Cellular and Molecular Neuroscience, Elastic Modulus, Tensile Strength, Genetics, medicine, Mechanical Properties, Animals, Computer Simulation, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Actin, Sodium channel, Cell Membrane, Biology and Life Sciences, Proteins, Cell Biology, Neuronal Dendrites, Axons, Actins, Rats, Cytoskeletal Proteins, 030104 developmental biology, nervous system, Models, Chemical, Cellular Neuroscience, Biophysics, Soma, Stress, Mechanical, 030217 neurology & neurosurgery, Neuroscience

Abstract

Super-resolution microscopy recently revealed that, unlike the soma and dendrites, the axon membrane skeleton is structured as a series of actin rings connected by spectrin filaments that are held under tension. Currently, the structure-function relationship of the axonal structure is unclear. Here, we used atomic force microscopy (AFM) to show that the stiffness of the axon plasma membrane is significantly higher than the stiffnesses of dendrites and somata. To examine whether the structure of the axon plasma membrane determines its overall stiffness, we introduced a coarse-grain molecular dynamics model of the axon membrane skeleton that reproduces the structure identified by super-resolution microscopy. Our proposed computational model accurately simulates the median value of the Young’s modulus of the axon plasma membrane determined by atomic force microscopy. It also predicts that because the spectrin filaments are under entropic tension, the thermal random motion of the voltage-gated sodium channels (Nav), which are bound to ankyrin particles, a critical axonal protein, is reduced compared to the thermal motion when spectrin filaments are held at equilibrium. Lastly, our model predicts that because spectrin filaments are under tension, any axonal injuries that lacerate spectrin filaments will likely lead to a permanent disruption of the membrane skeleton due to the inability of spectrin filaments to spontaneously form their initial under-tension configuration., Author summary Super-resolution microscopy has suggested that the actin cytoskeleton structure differ between various neuronal subcompartments. To determine the possible implication of the differing actin cytoskeleton structure, we determined the stiffness of the plasma membrane of neuronal subcompartments using atomic force microscopy (AFM). We found that axons are almost ~6 fold stiffer than the soma and ~2 fold stiffer than dendrites. By using a particle-based model for the surface membrane skeleton of the axon that comprises actin rings connected with spring filaments to represent the axonal structure, we show that regions neighboring actin rings are stiffer than areas between these rings. In these in between sub-regions, the spectrin filaments determine stiffness. Our modeling also shows that because the spectrin filaments are under tension, the thermal jitter of the actin-associated ankyrin particles, connected to the middle area of spectrin filaments, is minimal. As a result, we propose that the sodium channels bound to ankyrin particles will maintain an ordered distribution along the axon. We also predict that laceration of the spectrin filaments due to injury will cause a permanent damage to the axon since spontaneous repair of the spectrin network is not possible as spectrin filaments are under entropic tension.

Published

2017

40. Epilepsy-Associated KCNQ2 Channels Regulate Multiple Intrinsic Properties of Layer 2/3 Pyramidal Neurons

Author

Heun Soh, Virginia E. Hawkins, Daniel K. Mulkey, Anastasios V. Tzingounis, and Zachary Niday

Subjects

0301 basic medicine, Action Potentials, Mice, Transgenic, Neocortex, Biology, 03 medical and health sciences, Epilepsy, Mice, 0302 clinical medicine, KCNQ2 Potassium Channel, Conditional gene knockout, medicine, Animals, Humans, Research Articles, Membrane potential, Mice, Knockout, General Neuroscience, Sodium channel, Pyramidal Cells, Afterhyperpolarization, medicine.disease, Potassium channel, 030104 developmental biology, medicine.anatomical_structure, HEK293 Cells, Neuroscience, 030217 neurology & neurosurgery

Abstract

KCNQ2 potassium channels are critical for normal brain function, as both loss-of-function and gain-of-function KCNQ2 variants can lead to various forms of neonatal epilepsy. Despite recent progress, the full spectrum of consequences as a result of KCNQ2 dysfunction in neocortical pyramidal neurons is still unknown. Here, we report that conditional ablation ofKcnq2from mouse neocortex leads to hyperexcitability of layer 2/3 (L2/3) pyramidal neurons, exhibiting an increased input resistance and action potential frequency, as well as a reduced medium afterhyperpolarization (mAHP), a conductance partly mediated by KCNQ2 channels. Importantly, we show that introducing the KCNQ2 loss-of-function variant KCNQ2I205Vinto L2/3 pyramidal neurons usingin uteroelectroporation also results in a hyperexcitable phenotype similar to the conditional knock-out. KCNQ2I205Vhas a right-shifted conductance-to-voltage relationship, suggesting loss of KCNQ2 channel activity at subthreshold membrane potentials is sufficient to drive large changes in L2/3 pyramidal neuronal excitability even in the presence of an intact mAHP. We also found that the changes in excitability followingKcnq2ablation are accompanied by alterations at action potential properties, including action potential amplitude inKcnq2-null neurons. Importantly, partial inhibition of Nav1.6 channels was sufficient to counteract the hyperexcitability ofKcnq2-null neurons. Therefore, our work shows that loss of KCNQ2 channels alters the intrinsic neuronal excitability and action potential properties of L2/3 pyramidal neurons, and identifies Nav1.6 as a new potential molecular target to reduce excitability in patients with KCNQ2 encephalopathy.SIGNIFICANCE STATEMENTKCNQ2 channels are critical for the development of normal brain function, as KCNQ2 variants could lead to epileptic encephalopathy. However, the role of KCNQ2 channels in regulating the properties of neocortical neurons is largely unexplored. Here, we find thatKcnq2ablation or loss-of-function at subthreshold membrane potentials leads to increased neuronal excitability of neocortical layer 2/3 (L2/3) pyramidal neurons. We also demonstrate thatKcnq2ablation unexpectedly leads to a larger action potential amplitude. Importantly, we propose the Nav1.6 channel as a new molecular target for patients with KCNQ2 encephalopathy, as partial inhibition of these channels counteracts the increased L2/3 pyramidal neuron hyperexcitability ofKcnq2-null neurons.

Published

2017

41. Hippocalcin and KCNQ Channels Contribute to the Kinetics of the Slow Afterhyperpolarization

Author

Anastasios V. Tzingounis, Masaaki Kobayashi, Kwang S. Kim, and Ken Takamatsu

Subjects

Male, Biophysics, chemistry.chemical_element, Gating, Phenylenediamines, Calcium, Membrane Potentials, Gene Knockout Techniques, Mice, chemistry.chemical_compound, Hippocalcin, Animals, Channels and Transporters, Neurons, Membrane potential, KCNQ Potassium Channels, biology, Retigabine, CA3 Region, Hippocampal, Potassium channel, Kinetics, chemistry, Biochemistry, Slow afterhyperpolarization, Knockout mouse, biology.protein, Female, Carbamates, Neuroscience

Abstract

The calcium-activated slow afterhyperpolarization (sAHP) is a potassium conductance implicated in many physiological functions of the brain including memory, aging, and epilepsy. In large part, the sAHP’s importance stems from its exceedingly long-lasting time-course, which integrates action potential-induced calcium signals and allows the sAHP to control neuronal excitability and prevent runaway firing. Despite its role in neuronal physiology, the molecular mechanisms that give rise to its unique kinetics are, to our knowledge, still unknown. Recently, we identified KCNQ channels as a candidate potassium channel family that can contribute to the sAHP. Here, we test whether KCNQ channels shape the sAHP rise and decay kinetics in wild-type mice and mice lacking Hippocalcin, the putative sAHP calcium sensor. Application of retigabine to speed KCNQ channel activation accelerated the rise of the CA3 pyramidal neuron sAHP current in both wild-type and Hippocalcin knockout mice, indicating that the gating of KCNQ channels limits the sAHP activation. Interestingly, we found that the decay of the sAHP was prolonged in Hippocalcin knockout mice, and that the decay was sensitive to retigabine modulation, unlike in wild-type mice. Together, our results demonstrate that sAHP activation in CA3 pyramidal neurons is critically dependent on KCNQ channel kinetics whereas the identity of the sAHP calcium sensor determines whether KCNQ channel kinetics also limit the sAHP decay.

Published

2012

42. Topography of Native SK Channels Revealed by Force Nanoscopy in Living Neurons

Author

Jamie L. Maciaszek, Randall S. Walikonis, Heun Soh, George Lykotrafitis, and Anastasios V. Tzingounis

Subjects

Cell physiology, Patch-Clamp Techniques, Small-Conductance Calcium-Activated Potassium Channels, Green Fluorescent Proteins, Biophysics, Hippocampal formation, Microscopy, Atomic Force, Transfection, Apamin, Hippocampus, Rats, Sprague-Dawley, SK channel, chemistry.chemical_compound, Animals, Humans, Protein Isoforms, Patch clamp, Cells, Cultured, Ion channel, Neurons, General Neuroscience, Colforsin, Dendrites, Anatomy, Electric Stimulation, Potassium channel, Rats, Transport protein, Protein Transport, Animals, Newborn, chemistry, Brief Communications, Protein Binding

Abstract

The spatial distribution of ion channels is an important determinant of neuronal excitability. However, there are currently no quantitative techniques to map endogenous ion channels with single-channel resolution in living cells. Here, we demonstrate that integration of pharmacology with single-molecule atomic force microscopy (AFM) allows for the high-resolution mapping of native potassium channels in living neurons. We focus on calcium-activated small conductance (SK) potassium channels, which play a critical role in brain physiology. By linking apamin, a toxin that specifically binds to SK channels, to the tip of an AFM cantilever, we are able to detect binding events between the apamin and SK channels. We find that native SK channels from rat hippocampal neurons reside primarily in dendrites as single entities and in pairs. We also show that SK channel dendritic distribution is dynamic and under the control of protein kinase A. Our study demonstrates that integration of toxin pharmacology with single-molecule AFM can be used to quantitatively map individual native ion channels in living cells, and thus provides a new tool for the study of ion channels in cellular physiology.

Published

2012

43. Cortical KCNQ2/3 channels; insights from knockout mice

Author

Heun Soh, Anastasios V. Tzingounis, and Zachary Niday

Subjects

Pediatric epilepsy, Epilepsy, business.industry, Pyramidal Cells, Biophysics, food and beverages, Action Potentials, Nerve Tissue Proteins, Articles, Pharmacology, medicine.disease, Biochemistry, Potassium channel, KCNQ3 Potassium Channel, Knockout mouse, M current, medicine, Animals, KCNQ2 Potassium Channel, business, Neuroscience, Brain function, Gene Deletion

Abstract

KCNQ2 and KCNQ3 potassium channels have emerged as central regulators of pyramidal neuron excitability and spiking behavior. However, despite an abundance of evidence demonstrating that KCNQ2/3 heteromers underlie critical potassium conductances, it is unknown whether KCNQ2, KCNQ3, or both are obligatory for maintaining normal pyramidal neuron excitability. Here, we demonstrate that conditional deletion of Kcnq2 from cerebral cortical pyramidal neurons in mice results in abnormal electrocorticogram activity and early death, whereas similar deletion of Kcnq3 does not. At the cellular level, Kcnq2-null, but not Kcnq3-null, CA1 pyramidal neurons show increased excitability manifested as a decreased medium afterhyperpolarization and a longer-lasting afterdepolarization. As a result, these Kcnq2-deficient neurons are hyperexcitable, responding to current injections with an increased number and frequency of action potentials. Biochemically, the Kcnq2 deficiency secondarily results in a substantial loss of KCNQ3 and KCNQ5 protein levels, whereas loss of Kcnq3 only leads to a modest reduction of other KCNQ channels. Consistent with this finding, KCNQ allosteric activators can still markedly dampen neuronal excitability in Kcnq3-null pyramidal neurons, but have only weak effects in Kcnq2-null pyramidal neurons. Together, our data reveal the indispensable function of KCNQ2 channels at both the cellular and systems levels, and demonstrate that pyramidal neurons have near normal excitability in the absence of KCNQ3 channels.

Published

2014

44. Molecular underpinnings of ventral surface chemoreceptor function: focus on KCNQ channels

Author

Ana C. Takakura, Thiago S. Moreira, Joanna M. Hawryluk, Daniel K. Mulkey, Anastasios V. Tzingounis, and Virginia E. Hawkins

Subjects

Chemoreceptor, Raphe, KCNQ Potassium Channels, Physiology, Effector, Respiration, Biology, Serotonergic, medicine.disease, Chemoreceptor Cells, Epilepsy, FISIOLOGIA RESPIRATÓRIA E CIRCULATÓRIA, Kcnq channels, medicine, Animals, Humans, Symposium Section Reviews: New Advances in the Neural Control of Breathing, Respiratory system, Neuroscience, Loss function, Brain Stem

Abstract

Central chemoreception is the mechanism by which CO₂/H(+) -sensitive neurons (i.e. chemoreceptors) regulate breathing in response to changes in tissue CO₂/H(+) . Neurons in the retrotrapezoid nucleus (RTN) directly regulate breathing in response to changes in tissue CO₂/H(+) and function as a key locus of respiratory control by integrating information from several respiratory centres, including the medullary raphe. Therefore, chemosensitive RTN neurons appear to be critically important for maintaining breathing, thus understanding molecular mechanisms that regulate RTN chemoreceptor function may identify therapeutic targets for the treatment of respiratory control disorders. We have recently shown that KCNQ (Kv7) channels in the RTN are essential determinants of spontaneous activity ex vivo, and downstream effectors for serotonergic modulation of breathing. Considering that loss of function mutations in KCNQ channels can cause certain types of epilepsy including those associated with sudden unexplained death in epilepsy (SUDEP), we propose that dysfunctions of KCNQ channels may be one cause for epilepsy and respiratory problems associated with SUDEP. In this review, we will summarize the role of KCNQ channels in the regulation of RTN chemoreceptor function, and suggest that these channels represent useful therapeutic targets for the treatment of respiratory control disorders.

Published

2014

45. EAAT2 (GLT-1; slc1a2) Glutamate Transporters Reconstituted in Liposomes Argues against Heteroexchange Being Substantially Faster than Net Uptake

Author

Xiaoyu Wang, Yun Zhou, Anastasios V. Tzingounis, H. Peter Larsson, and Niels C. Danbolt

Subjects

Time Factors, Sodium, chemistry.chemical_element, Glutamic Acid, Mice, Transgenic, In Vitro Techniques, Models, Biological, Membrane Potentials, Glutamatergic, Mice, medicine, Animals, Computer Simulation, Axon, Amino Acids, Rats, Wistar, Membrane potential, Valinomycin, biology, Ionophores, General Neuroscience, SLC1A2, Glutamate receptor, Substrate (chemistry), Brain, Articles, Rats, Mice, Inbred C57BL, medicine.anatomical_structure, chemistry, Biochemistry, Excitatory Amino Acid Transporter 2, Liposomes, biology.protein, Biophysics, Potassium, Cattle, Neurotransmitter transport

Abstract

The EAAT2 glutamate transporter, accounts for >90% of hippocampal glutamate uptake. Although EAAT2 is predominantly expressed in astrocytes, ∼10% of EAAT2 molecules are found in axon terminals. Despite the lower level of EAAT2 expression in glutamatergic terminals, when hippocampal slices are incubated with low concentration ofd-aspartate (an EAAT2 substrate), axon terminals accumulated-aspartate as quickly as astroglia. This implies an unexplained mismatch between the distribution of EAAT2 protein and of EAAT2-mediated transport activity. One hypothesis is that (1) heteroexchange of internal substrate with external substrate is considerably faster than net uptake and (2) terminals favor heteroexchange because of high levels of internal glutamate. However, it is currently unknown whether heteroexchange and uptake have similar or different rates. To address this issue, we used a reconstituted system to compare the relative rates of the two processes in rat and mice. Net uptake was sensitive to changes in the membrane potential and was stimulated by external permeable anions in agreement with the existence of an uncoupled anion conductance. By using the latter, we also demonstrate that the rate of heteroexchange also depends on the membrane potential. Additionally, our data further suggest the presence of a sodium leak in EAAT2. By incorporating the new findings in our previous model of glutamate uptake by EAAT2, we predict that the voltage sensitivity of exchange is caused by the voltage-dependent third Na+binding. Further, both our experiments and simulations suggest that the relative rates of net uptake and heteroexchange are comparable in EAAT2.

Published

2014

46. Conditional deletions of epilepsy-associated KCNQ2 and KCNQ3 channels from cerebral cortex cause differential effects on neuronal excitability

Author

Rima Pant, Joseph J. LoTurco, Heun Soh, and Anastasios V. Tzingounis

Subjects

Allosteric regulation, Action Potentials, Nerve Tissue Proteins, Biology, Afterdepolarization, KCNQ3 Potassium Channel, Epilepsy, Mice, KCNQ2 Potassium Channel, M current, medicine, Animals, Autocommentaries, General Neuroscience, Pyramidal Cells, food and beverages, Afterhyperpolarization, medicine.disease, Potassium channel, Mice, Inbred C57BL, medicine.anatomical_structure, Cerebral cortex, Neuroscience, Gene Deletion

Abstract

KCNQ2 and KCNQ3 potassium channels have emerged as central regulators of pyramidal neuron excitability and spiking behavior. However, despite an abundance of evidence demonstrating that KCNQ2/3 heteromers underlie critical potassium conductances, it is unknown whether KCNQ2, KCNQ3, or both are obligatory for maintaining normal pyramidal neuron excitability. Here, we demonstrate that conditional deletion ofKcnq2from cerebral cortical pyramidal neurons in mice results in abnormal electrocorticogram activity and early death, whereas similar deletion ofKcnq3does not. At the cellular level,Kcnq2-null, but notKcnq3-null, CA1 pyramidal neurons show increased excitability manifested as a decreased medium afterhyperpolarization and a longer-lasting afterdepolarization. As a result, theseKcnq2-deficient neurons are hyperexcitable, responding to current injections with an increased number and frequency of action potentials. Biochemically, theKcnq2deficiency secondarily results in a substantial loss of KCNQ3 and KCNQ5 protein levels, whereas loss ofKcnq3only leads to a modest reduction of other KCNQ channels. Consistent with this finding, KCNQ allosteric activators can still markedly dampen neuronal excitability inKcnq3-null pyramidal neurons, but have only weak effects inKcnq2-null pyramidal neurons. Together, our data reveal the indispensable function of KCNQ2 channels at both the cellular and systems levels, and demonstrate that pyramidal neurons have near normal excitability in the absence of KCNQ3 channels.

Published

2014

47. Regulation of SK Channel Spatial Distribution by Tonic PKA

Author

Anastasios V. Tzingounis, Krithika Abiraman, and George Lykotrafitis

Subjects

SK channel, chemistry.chemical_compound, Membrane, Chemistry, Stereochemistry, Atomic force microscopy, Synaptic plasticity, Biophysics, Spatial distribution, Apamin, Potassium conductance, Tonic (physiology)

Abstract

Introduction: Small-conductance Ca2+-activated K+ (SK) channels mediate a ubiquitous expressed potassium conductance in the brain involved in synaptic plasticity and learning and memory. SK channel spatial distribution shows a polarized topographic expression being highly enriched in neuronal dendrites with limited expression on somatic membranes. However, the mechanism that controls this spatial distribution is unknown. To investigate the mechanisms that control the spatial distribution of SK channels at the single molecule level we combine single molecule atomic force microscopy and toxin pharmacology.Methods and results: AFM tip functionalized with apamin, a SK channel blocker, is used to detect the distribution of SK channels in living neurons by measuring the binding forces between apamin and SK channels. Employing the above technique, we test the effect of PKA on the clustering and dendritic localization of SK channels. Here, we show that SK2 channel nanoclustering is under the control of cAMP and PKA activity and demonstrate that SK2 channel polarized distribution in neurons is dictated by basal PKA activity.Conclusion: Our work reveals a new level of regulation of SK2 channels by PKA and also demonstrates for the first time that SK2 spatial distribution is plastic.

Published

2014

48. Chemosensitive neurons in the retrotrapezoid nucleus (RTN) express SK channels with low Ca2+ affinity

Author

Xinnian Chen, Daniel K. Mulkey, Anastasios V. Tzingounis, and Joanna M. Hawryluk

Subjects

SK channel, Chemistry, Genetics, Retrotrapezoid nucleus, Molecular Biology, Biochemistry, Biotechnology, Cell biology

Published

2013

49. HCN channels contribute to serotonergic modulation of chemoreceptors in the retrotrapezoid nucleus

Author

Virginia E. Hawkins, Anastasios V. Tzingounis, Donny Williams, Joanna M. Hawryluk, Daniel K. Mulkey, Ana C. Takakura, and Thaigo Moreira

Subjects

Chemoreceptor, Chemistry, Modulation, Genetics, Retrotrapezoid nucleus, Serotonergic, Molecular Biology, Biochemistry, Neuroscience, Biotechnology

Published

2013

50. KCNQ channels regulate activity of chemosensitive neurons in the retrotrapezoid nucleus

Author

Ana C. Takakura, Daniel K. Mulkey, Thiago S. Moreira, Ian C. Wenker, Joanna M. Hawryluk, and Anastasios V. Tzingounis

Subjects

Kcnq channels, Chemistry, Genetics, Retrotrapezoid nucleus, Molecular Biology, Biochemistry, Neuroscience, Biotechnology

Published

2013