PIP2 Mediated Inhibition of TREK Potassium Currents by Bradykinin in Mouse Sympathetic Neurons

Rivas-Ramírez, Paula; Reboreda, Antonio; Rueda‐Ruzafa, Lola; Herrera-Pérez, Salvador; Lamas, José Antonio

doi:10.3390/ijms21020389

Cited by 9 publications

(10 citation statements)

References 74 publications

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“…Wild-type and genetically-engineered mice are widely used to understand the mechanisms by which hypoxic challenges elicit carotid body-dependent and -independent ventilatory responses (He et al, 2000(He et al, , 2002(He et al, , 2003Kline and Prabhakar, 2000;Pérez-García et al, 2004;Kline et al, 2005;Pichard et al, 2015;Gao et al, 2017;Wang et al, 2017;Ortega-Sáenz et al, 2018;Peng et al, 2018;Prabhakar et al, 2018). The morphology, neurophysiology and neuropharmacology of the mouse CSC-SCG has received considerable investigation over the years (Black et al, 1972;Yokota and Yamauchi, 1974;Banks and Walter, 1975;Inoue, 1975;Lewis and Burton, 1977;Forehand, 1985;Kidd and Heath, 1988;Gibbins, 1991;Kasa et al, 1991;Little and Heath, 1994;Jobling and Gibbins, 1999;El-Fadaly and Kummer, 2003;David et al, 2010;Cadaveira-Mosquera et al, 2012;Pashai et al, 2012;Alberola-Die et al, 2013;Liu and Bean, 2014;Martinez-Pinna et al, 2018;Mitsuoka et al, 2018;Feldman-Goriachnik and Hanani, 2019;Simeone et al, 2019;Rivas-Ramírez et al, 2020). Mouse tissues that receive post-ganglionic projections from the SCG have also been heavily investigated (Krieger et al, 1976;García et al, 1988;…”

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confidence: 99%

Loss of Cervical Sympathetic Chain Input to the Superior Cervical Ganglia Affects the Ventilatory Responses to Hypoxic Challenge in Freely-Moving C57BL6 Mice

et al. 2021

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The cervical sympathetic chain (CSC) innervates post-ganglionic sympathetic neurons within the ipsilateral superior cervical ganglion (SCG) of all mammalian species studied to date. The post-ganglionic neurons within the SCG project to a wide variety of structures, including the brain (parenchyma and cerebral arteries), upper airway (e.g., nasopharynx and tongue) and submandibular glands. The SCG also sends post-ganglionic fibers to the carotid body (e.g., chemosensitive glomus cells and microcirculation), however, the function of these connections are not established in the mouse. In addition, nothing is known about the functional importance of the CSC-SCG complex (including input to the carotid body) in the mouse. The objective of this study was to determine the effects of bilateral transection of the CSC on the ventilatory responses [e.g., increases in frequency of breathing (Freq), tidal volume (TV) and minute ventilation (MV)] that occur during and following exposure to a hypoxic gas challenge (10% O2 and 90% N2) in freely-moving sham-operated (SHAM) adult male C57BL6 mice, and in mice in which both CSC were transected (CSCX). Resting ventilatory parameters (19 directly recorded or calculated parameters) were similar in the SHAM and CSCX mice. There were numerous important differences in the responses of CSCX and SHAM mice to the hypoxic challenge. For example, the increases in Freq (and associated decreases in inspiratory and expiratory times, end expiratory pause, and relaxation time), and the increases in MV, expiratory drive, and expiratory flow at 50% exhaled TV (EF50) occurred more quickly in the CSCX mice than in the SHAM mice, although the overall responses were similar in both groups. Moreover, the initial and total increases in peak inspiratory flow were higher in the CSCX mice. Additionally, the overall increases in TV during the latter half of the hypoxic challenge were greater in the CSCX mice. The ventilatory responses that occurred upon return to room-air were essentially similar in the SHAM and CSCX mice. Overall, this novel data suggest that the CSC may normally provide inhibitory input to peripheral (e.g., carotid bodies) and central (e.g., brainstem) structures that are involved in the ventilatory responses to hypoxic gas challenge in C57BL6 mice.

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confidence: 99%

Loss of Cervical Sympathetic Chain Input to the Superior Cervical Ganglia Affects the Ventilatory Responses to Hypoxic Challenge in Freely-Moving C57BL6 Mice

et al. 2021

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“…The PLC activator diminishes the PI(4,5)P2 pool [ 46 ] and increases the cytoplasmic Ca 2+ concentration, but the Ca 2+ increase was insufficient to maintain the channel activity. TREK-2 channels are dependent on PI(4,5)P2; we therefore focused on the mechanism of TREK-2-like channel activation based on its interaction with PI(4,5)P2 [ 29 , 32 , 33 , 40 ]. In particular, we considered possible mechanisms involving both Ca 2+ and PI(4,5)P2.…”

Section: Discussionmentioning

confidence: 99%

“…TREK channels are downregulated by the activation of G-coupled receptors activating phospholipase C, which hydrolyses PI (4,5)P2 to diacylglycerol (DAG) and inositol triphosphate (IP3), with the latter releasing Ca 2+ from internal stores. The depletion of PI(4,5)P2 caused by hydrolysis and the resulting loss of membrane interaction of the C-terminus inhibits TREK channels [30,32,33]. TREK channels are also inhibited by the phosphorylation of multiple residues on the cytoplasmic C-terminus domain by protein kinase A and C following the stimulation of G-coupled receptors [12,[34][35][36].…”

Section: Introductionmentioning

confidence: 99%

Activity of TREK-2-like Channels in the Pyramidal Neurons of Rat Medial Prefrontal Cortex Depends on Cytoplasmic Calcium

Dworakowska

Gawlak

Nurowska

2021

Biology

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TREK-2-like channels in the pyramidal neurons of rat prefrontal cortex are characterized by a wide range of spontaneous activity—from very low to very high—independent of the membrane potential and the stimuli that are known to activate TREK-2 channels, such as temperature or membrane stretching. The aim of this study was to discover what factors are involved in high levels of TREK-2-like channel activity in these cells. Our research focused on the PI(4,5)P2-dependent mechanism of channel activity. Single-channel patch clamp recordings were performed on freshly dissociated pyramidal neurons of rat prefrontal cortexes in both the cell-attached and inside-out configurations. To evaluate the role of endogenous stimulants, the activity of the channels was recorded in the presence of a PI(4,5)P2 analogue (PI(4,5)P2DiC8) and Ca2+. Our research revealed that calcium ions are an important factor affecting TREK-2-like channel activity and kinetics. The observation that calcium participates in the activation of TREK-2-like channels is a new finding. We showed that PI(4,5)P2-dependent TREK-2 activity occurs when the conditions for PI(4,5)P2/Ca2+ nanocluster formation are met. We present a possible model explaining the mechanism of calcium action.

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“…It is well known that RMP changes when I M is modulated through GPCRs by muscarinic, bradykinin, purinergic and angiotensin II agonists [10,32,33] or directly by blockers such as linopirdine and XE991 [10,29] in SCG neurons. In 1996, the first member of the K2P family was described [7] and this potassium channel family is also involved in the maintenance of the RMP and excitability [14,34]. Because TREK channels are very sensitive to temperature [35], the main objective of this work was to determine the contribution of each of these two currents (M and TREK) to the resting membrane potential at physiological temperatures.…”

Section: Discussionmentioning

confidence: 99%

“…Nevertheless, we have seen recently that TREK-2 channels in mouse SCG neurons are also inhibited by the muscarinic agonist oxo-M through G-proteins and a second messenger cascade [13]. Moreover, inhibition of TREK-2 current [14] and M-current [15] by bradykinin hormone depolarizes the RMP. On the other hand, the inhibition of TREK currents with fluoxetine [16] produced a depolarization of the membrane potential and reduced the latency to the first evoked action potential, without affecting adaptation [6] at room temperature.…”

Section: Introductionmentioning

confidence: 99%

Contribution of KCNQ and TREK Channels to the Resting Membrane Potential in Sympathetic Neurons at Physiological Temperature

Rivas-Ramírez

Reboreda

Rueda‐Ruzafa

et al. 2020

IJMS

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The ionic mechanisms controlling the resting membrane potential (RMP) in superior cervical ganglion (SCG) neurons have been widely studied and the M-current (IM, KCNQ) is one of the key players. Recently, with the discovery of the presence of functional TREK-2 (TWIK-related K+ channel 2) channels in SCG neurons, another potential main contributor for setting the value of the resting membrane potential has appeared. In the present work, we quantified the contribution of TREK-2 channels to the resting membrane potential at physiological temperature and studied its role in excitability using patch-clamp techniques. In the process we have discovered that TREK-2 channels are sensitive to the classic M-current blockers linopirdine and XE991 (IC50 = 0.310 ± 0.06 µM and 0.044 ± 0.013 µM, respectively). An increase from room temperature (23 °C) to physiological temperature (37 °C) enhanced both IM and TREK-2 currents. Likewise, inhibition of IM by tetraethylammonium (TEA) and TREK-2 current by XE991 depolarized the RMP at room and physiological temperatures. Temperature rise also enhanced adaptation in SCG neurons which was reduced due to TREK-2 and IM inhibition by XE991 application. In summary, TREK-2 and M currents contribute to the resting membrane potential and excitability at room and physiological temperature in the primary culture of mouse SCG neurons.

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PIP2 Mediated Inhibition of TREK Potassium Currents by Bradykinin in Mouse Sympathetic Neurons

Cited by 9 publications

References 74 publications

Loss of Cervical Sympathetic Chain Input to the Superior Cervical Ganglia Affects the Ventilatory Responses to Hypoxic Challenge in Freely-Moving C57BL6 Mice

Loss of Cervical Sympathetic Chain Input to the Superior Cervical Ganglia Affects the Ventilatory Responses to Hypoxic Challenge in Freely-Moving C57BL6 Mice

Activity of TREK-2-like Channels in the Pyramidal Neurons of Rat Medial Prefrontal Cortex Depends on Cytoplasmic Calcium

Contribution of KCNQ and TREK Channels to the Resting Membrane Potential in Sympathetic Neurons at Physiological Temperature

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