Your search keyword '"Gamper, Nikita"' showing total 11 results

1. Kv7 Channels and Excitability Disorders

Author

Jones, Frederick, Gamper, Nikita, Gao, Haixia, Barrett, James E., Editor-in-Chief, Flockerzi, Veit, Editorial Board Member, Frohman, Michael A., Editorial Board Member, Geppetti, Pierangelo, Editorial Board Member, Hofmann, Franz B., Editorial Board Member, Kuner, Rohini, Editorial Board Member, Michel, Martin C., Editorial Board Member, Page, Clive P., Editorial Board Member, Wang, KeWei, Editorial Board Member, Rosenthal, Walter, Editorial Board Member, and Gamper, Nikita, editor

Published

2021

2. Intracellular zinc activates KCNQ channels by reducing their dependence on phosphatidylinositol 4,5-bisphosphate

Author

Gao, Haixia, Boillat, Aurélien, Huang, Dongyang, Liang, Ce, Peers, Chris, and Gamper, Nikita

Published

2017

3. Intracellular zinc activates KCNQ channels by reducing their dependence on phosphatidylinositol 4,5-bisphosphate.

Author

Haixia Gao, Boillat, Aurélien, Dongyang Huang, Ce Liang, Peers, Chris, and Gamper, Nikita

Subjects

POTASSIUM channels, ZINC, PHOSPHATIDYLINOSITOLS, EPILEPSY, CELL membranes

Abstract

M-type (Kv7, KCNQ) potassium channels are proteins that control the excitability of neurons and muscle cells. Many physiological and pathological mechanisms of excitation operate via the suppression of M channel activity or expression. Conversely, pharmacological augmentation of M channel activity is a recognized strategy for the treatment of hyperexcitability disorders such as pain and epilepsy. However, physiological mechanisms resulting in M channel potentiation are rare. Here we report that intracellular free zinc directly and reversibly augments the activity of recombinant and native M channels. This effect is mechanistically distinct from the known redox-dependent KCNQ channel potentiation. Interestingly, the effect of zinc cannot be attributed to a single histidine- or cysteine-containing zinc-binding site within KCNQ channels. Instead, zinc dramatically reduces KCNQ channel dependence on its obligatory physiological activator, phosphatidylinositol 4,5-bisphosphate (PIP2). We hypothesize that zinc facilitates interactions of the lipid-facing interface of a KCNQ protein with the inner leaflet of the plasma membrane in a way similar to that promoted by PIP2. Because zinc is increasingly recognized as a ubiquitous intracellular second messenger, this discovery might represent a hitherto unknown native pathway of M channel modulation and provide a fresh strategy for the design of M channel activators for therapeutic purposes. [ABSTRACT FROM AUTHOR]

Published

2017

4. Spike propagation through the dorsal root ganglia in an unmyelinated sensory neuron: a modeling study.

Author

Sundt, Danielle, Gamper, Nikita, and Jaffe, David B.

Subjects

*NAILS (Hardware), *SENSORY ganglia, *SENSORY neurons, *COMPUTER simulation, *PAIN management

Abstract

Unmyelinated C-fibers are a major type of sensory neurons conveying pain information. Action potential conduction is regulated by the bifurcation (Tjunction) of sensory neuron axons within the dorsal root ganglia (DRG). Understanding how C-fiber signaling is influenced by the morphology of the T-junction and the local expression of ion channels is important for understanding pain signaling. In this study we used biophysical computer modeling to investigate the influence of axon morphology within the DRG and various membrane conductances on the reliability of spike propagation. As expected, calculated input impedance and the amplitude of propagating action potentials were both lowest at the T-junction. Propagation reliability for single spikes was highly sensitive to the diameter of the stem axon and the density of voltage-gated Na+ channels. A model containing only fast voltage-gated Na+ and delayed-rectifier K+ channels conducted trains of spikes up to frequencies of 110 Hz. The addition of slowly activating KCNQ channels (i.e., KV7 or M-channels) to the model reduced the following frequency to 30 Hz. Hyperpolarization produced by addition of a much slower conductance, such as a Ca2+-dependent K+ current, was needed to reduce the following frequency to 6 Hz. Attenuation of driving force due to ion accumulation or hyperpolarization produced by a Na+-K+ pump had no effect on following frequency but could influence the reliability of spike propagation mutually with the voltage shift generated by a Ca2+-dependent K current. These simulations suggest how specific ion channels within the DRG may contribute toward therapeutic treatments for chronic pain. [ABSTRACT FROM AUTHOR]

Published

2015

5. Functional significance of M-type potassium channels in nociceptive cutaneous sensory endings.

Author

Passmore, Gayle M., Reilly, Joanne M., Thakur, Matthew, Keasberry, Vanessa N., Marsh, Stephen J., Dickenson, Anthony H., Brown, David A., and Gamper, Nikita

Subjects

POTASSIUM channels, NEURONS, SOMATOSENSORY evoked potentials, SENSORY neurons, NEUROSCIENCES

Abstract

M-channels carry slowly activating potassium currents that regulate excitability in a variety of central and peripheral neurons. Functional M-channels and their Kv7 channel correlates are expressed throughout the somatosensory nervous system where they may play an important role in controlling sensory nerve activity. Here we show that Kv7.2 immunoreactivity is expressed in the peripheral terminals of nociceptive primary afferents. Electrophysiological recordings from single afferents in vitro showed that block of M-channels by 3 μM XE991 sensitized Ad- but not C-fibers to noxious heat stimulation and induced spontaneous, ongoing activity at 32°C in many Aδ-fibers. These observations were extended in vivo: intraplantar injection of XE991 selectively enhanced the response of deep dorsal horn (DH) neurons to peripheral mid-range mechanical and higher range thermal stimuli, consistent with a selective effect on Aδ-fiber peripheral terminals. These results demonstrate an important physiological role of M-channels in controlling nociceptive Aδ-fiber responses and provide a rationale for the nocifensive behaviors that arise following intraplantar injection of the M-channel blocker XE991. [ABSTRACT FROM AUTHOR]

Published

2012

6. Inhibition of M Current in Sensory Neurons by Exogenous Proteases: A Signaling Pathway Mediating Inflammatory Nociception.

Author

Linley, John E., Rose, Kirstin, Patil, Mayur, Robertson, Brian, Akopian, Armen N., and Gamper, Nikita

Subjects

SENSORY neurons, NOCICEPTORS, POTASSIUM channels, PERIPHERAL nervous system, PHOSPHOLIPASES, NEUROSCIENCES

Abstract

Inflammatory pain is thought to be mediated in part through the action of inflammatory mediators on membrane receptors of peripheral nerve terminals, however, the downstream signaling events which lead to pain are poorly understood. In this study we investigated the nociceptive pathways induced by activation of protease-activated receptor 2 (PAR-2) in damage-sensing (nociceptive) neurons from rat dorsal root ganglion (DRG).We found that activation of PAR-2 in these cells strongly inhibited M-type potassium currents (conducted by Kv7 potassium channels). Such inhibition caused depolarization of the neuronal resting membrane potential leading, ultimately, to nociception. Consistent with this mechanism, injection of the specific M channel blocker XE991 into rat paw induced nociception in a concentration-dependent manner. Injection of a PAR-2 agonist peptide also induced nociception but coinjection of XE991 and the PAR-2 agonist did not result in summation of nociception, suggesting that the action of both agents may share a similar mechanism. We also studied the signaling pathway of M current inhibition by PAR-2 using patch-clamp and fluorescence imaging of DRG neurons. These experiments revealed that the PAR-2 effect was mediated by phospholipase C (PLC). Further experiments demonstrated that M current inhibition required concurrent rises in cytosolic Ca2+ concentration and depletion of membrane phosphatidylinositol 4,5-bisphosphate (PIP2). We propose that PLC- and Ca2+/PIP2-mediated inhibition of M current in sensory neurons may represent one of the general mechanisms underlying pain produced by inflammatory mediators, and may therefore open up a new therapeutic window for treatment of this major clinical problem. [ABSTRACT FROM AUTHOR]

Published

2008

7. Oxidative modification of M-type K+ channels as a mechanism of cytoprotective neuronal silencing.

Author

Gamper, Nikita, Zaika, Oleg, Yang Li, Martin, Pamela, Hernandez, Ciria C., Perez, Michael R., Wang, Andrew Y. C., Jaffe, David B., and Shapiro, Mark S.

Subjects

*CYSTEINE proteinases, *NEURONS, *CELLS, *HYDROGEN peroxide, *DISINFECTION & disinfectants, *OXIDATIVE stress, *OXIDATION-reduction reaction, *MOLECULAR biology

Abstract

Voltage-gated K+ channels of the Kv7 family underlie the neuronal M current that regulates action potential firing. Suppression of M current increases excitability and its enhancement can silence neurons. We here show that three of five Kv7 channels undergo strong enhancement of their activity by oxidative modification induced by physiological concentrations of hydrogen peroxide. A triple cysteine pocket in the channel S2–S3 linker is critical for this effect. Oxidation-induced enhancement of M current produced a hyperpolarization and a dramatic reduction of action potential firing frequency in rat sympathetic neurons. As hydrogen peroxide is robustly produced during hypoxia-induced oxidative stress, we used an oxygen/glucose deprivation neurodegeneration model that showed neuronal death to be severely accelerated by M current blockade. Such blockade had no effect on survival of normoxic neurons. This work describes a novel pathway of M-channel regulation and suggests a role for M channels in protective neuronal silencing during oxidative stress. [ABSTRACT FROM AUTHOR]

Published

2006

8. The use of Chinese hamster ovary (CHO) cells in the study of ion channels

Author

Gamper, Nikita, Stockand, James D., and Shapiro, Mark S.

Subjects

*OVARIES, *CELLS, *MEMBRANE proteins, *GENETIC transformation

Abstract

Abstract: The line of epithelial-like Chinese hamster ovary (CHO) cells was initiated by T.T. Puck in 1957. Since then, CHO cells have become a widely used mammalian expression system in industry and science. This paper discusses the different features of CHO cell physiology as well as the specific aspects of using these cells for ion channel studies; among the discussed features are the culturing and transfection of CHO cells, details of electrophysiological recordings from them and applications for the study of ion channel physiology and pharmacology. Examples of successful reconstitution of mammalian ion channels in CHO cells discussed in the paper include reconstitution of KCNQ channel regulation by muscarinic acetylcholine receptors and the study of the amiloride-sensitivity of epithelial sodium channels (ENaC). [Copyright &y& Elsevier]

Published

2005

9. Control of Biophysical and Pharmacological Properties of Potassium Channels by Ancillary Subunits

Author

Abbott, Geoffrey W., Barrett, James E., Editor-in-Chief, Flockerzi, Veit, Editorial Board Member, Frohman, Michael A., Editorial Board Member, Geppetti, Pierangelo, Editorial Board Member, Hofmann, Franz B., Editorial Board Member, Kuner, Rohini, Editorial Board Member, Michel, Martin C., Editorial Board Member, Page, Clive P., Editorial Board Member, Wang, KeWei, Editorial Board Member, Rosenthal, Walter, Editorial Board Member, and Gamper, Nikita, editor

Published

2021

10. Control of somatic membrane potential in nociceptive neurons and its implications for peripheral nociceptive transmission.

Author

Du, Xiaona, Hao, Han, Gigout, Sylvain, Huang, Dongyang, Yang, Yuehui, Li, Li, Wang, Caixue, Sundt, Danielle, Jaffe, David B., Zhang, Hailin, and Gamper, Nikita

Subjects

*MEMBRANE potential, *SOMATIC cells, *NEURONS, *NEURAL transmission, *PERIPHERAL nervous system, *SENSORY ganglia

Abstract

Peripheral sensory ganglia contain somata of afferent fibres conveying somatosensory inputs to the central nervous system. Growing evidence suggests that the somatic/perisomatic region of sensory neurons can influence peripheral sensory transmission. Control of resting membrane potential (E rest ) is an important mechanism regulating excitability, but surprisingly little is known about how E rest is regulated in sensory neuron somata or how changes in somatic/perisomatic E rest affect peripheral sensory transmission. We first evaluated the influence of several major ion channels on E rest in cultured small-diameter, mostly capsaicin-sensitive (presumed nociceptive) dorsal root ganglion (DRG) neurons. The strongest and most prevalent effect on E rest was achieved by modulating M channels, K2P and 4-aminopiridine-sensitive K V channels, while hyperpolarization-activated cyclic nucleotide-gated, voltage-gated Na + , and T-type Ca 2+ channels to a lesser extent also contributed to E rest . Second, we investigated how varying somatic/perisomatic membrane potential, by manipulating ion channels of sensory neurons within the DRG, affected peripheral nociceptive transmission in vivo. Acute focal application of M or K ATP channel enhancers or a hyperpolarization-activated cyclic nucleotide-gated channel blocker to L5 DRG in vivo significantly alleviated pain induced by hind paw injection of bradykinin. Finally, we show with computational modelling how somatic/perisomatic hyperpolarization, in concert with the low-pass filtering properties of the t-junction within the DRG, can interfere with action potential propagation. Our study deciphers a complement of ion channels that sets the somatic E rest of nociceptive neurons and provides strong evidence for a robust filtering role of the somatic and perisomatic compartments of peripheral nociceptive neuron. [ABSTRACT FROM AUTHOR]

Published

2014

11. Transcriptional repression of the M channel subunit Kv7.2 in chronic nerve injury

Author

Rose, Kirstin, Ooi, Lezanne, Dalle, Carine, Robertson, Brian, Wood, Ian C., and Gamper, Nikita

Subjects

*GENETIC regulation, *TRANSCRIPTION factors, *NERVOUS system injuries, *HYPERALGESIA, *SENSORY neurons, *GENES

Abstract

Abstract: Neuropathic pain is a severe health problem for which there is a lack of effective therapy. A frequent underlying condition of neuropathic pain is a sustained overexcitability of pain-sensing (nociceptive) sensory fibres. Therefore, the identification of mechanisms for such abnormal neuronal excitability is of utmost importance for understanding neuropathic pain. Despite much effort, an inclusive model explaining peripheral overexcitability is missing. We investigated transcriptional regulation of the Kcnq2 gene, which encodes the Kv7.2 subunit of membrane potential-stabilizing M channel, in peripheral sensory neurons in a model of neuropathic pain—partial sciatic nerve ligation (PSNL). We show that Kcnq2 is the major Kcnq gene transcript in dorsal root ganglion (DRG); immunostaining and patch-clamp recordings from acute ganglionic slices verified functional expression of Kv7.2 in small-diameter nociceptive DRG neurons. Neuropathic injury induced substantial downregulation of Kv7.2 expression. Levels of repressor element 1–silencing transcription factor (REST), which is known to suppress Kcnq2 expression, were upregulated in response to neuropathic injury identifying the likely mechanism of Kcnq2 regulation. Behavioural experiments demonstrated that neuropathic hyperalgesia following PSNL developed faster than the downregulation of Kcnq2 expression could be detected, suggesting that this transcriptional mechanism may contribute to the maintenance rather than the initiation of neuropathic pain. Importantly, the decrease in the peripheral M channel abundance could be functionally compensated by peripherally applied M channel opener flupirtine, which alleviated neuropathic hyperalgesia. Our work suggests a novel mechanism for neuropathic overexcitability and brings focus on M channels and REST as peripheral targets for the treatment of neuropathic pain. Neuropathic injury induces transcriptional downregulation of the Kcnq2 potassium channel gene by the transcriptional suppressor repressor element 1–silencing transcription factor; this mechanism contributes to peripheral sensitization of the afferent fibres. [Copyright &y& Elsevier]

Published

2011