Prevention of brain damage after traumatic brain injury by pharmacological enhancement of KCNQ (Kv7, “M-type”) K<sup>+</sup> currents in neurons

Vigil, Fabio A; Bozdemir, Eda; Bugay, Vladislav; Chun, Sang H; Hobbs, MaryAnn; Sanchez, Isamar; Hastings, Shayne D.; Veraza, Rafael J.; Holstein, Deborah; Sprague, Shane; Carver, Chase M.; Cavazos, Jose ́E.; Brenner, Robert; Lechleiter, James D.; Shapiro, Mark S.

doi:10.1177/0271678x19857818

Cited by 43 publications

(38 citation statements)

References 129 publications

(201 reference statements)

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“…Using in situ hybridization, we confirmed that KCNQ2 transcription was increased after hyperexcitability challenge to the brain; however, KCNQ3 transcription was not altered. This is consistent with our previous finding of lack of KCNQ3 transcription in the cortex after TBI, despite increases to KCNQ2 (Vigil et al, ). As KCNQ3 is abundantly co‐assembled with KCNQ2 in neurons, any specified role of KCNQ3 plasticity in neuromodulation of hippocampus has yet to be revealed (Soh et al, ).…”

Section: Discussionsupporting

confidence: 94%

“…Specifically, upregulation of KCNQ2 expression can only occur in neurons that survive a deleterious insult that induces excitotoxicity, represented here by the stark contrast of signal between the types of principal neurons. We recently report a similar result concerning cortical neuron plasticity in responding to and surviving an adverse insult (Vigil et al, ).…”

Section: Resultssupporting

confidence: 70%

“…Furthermore, selective neuronal death occurs in the hippocampus 1–7 days after TBI that promotes further hyperexcitability (Golarai, Greenwood, Feeney, & Connor, ). We used the controlled cortical impact (CCI) model, as recently described (Vigil et al, ). Forty‐eight hours after CCI‐TBI, we investigated changes in relative KCNQ2 transcription in hippocampus using the KCNQ2 mRNA‐EGFP reporter mice.…”

Section: Resultsmentioning

confidence: 99%

“…The controlled cortical impact injury (CCI) traumatic brain injury (TBI) model uses a pneumatic impact device, as previously described by our group (Vigil et al, ). The CCI model causes a TBI but the skull remains intact with minimal hematoma (Hunt et al, ).…”

Section: Methodsmentioning

confidence: 99%

“…Similarly, transgenic suppression of M channels in mice results in epileptic phenotypes (Greene, Kosenko, & Hoshi, ; Niday et al, 2017; Peters, Hu, Pongs, Storm, & Isbrandt, ; Singh et al, 2008; Soh, Pant, LoTurco, & Tzingounis, ). Whereas the role of M channels in acquired epileptogenesis has not been well characterized, evidence suggests that M‐channel openers can serve a protective role in preventing seizures and other insults that can progress to epilepsy, such as stroke and traumatic brain injury (Bierbower, Choveau, Lechleiter, & Shapiro, ; Sampath, Valdez, White, & Raol, ; Vigil et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Functional responses of the hippocampus to hyperexcitability depend on directed, neuron‐specific KCNQ2 K⁺ channel plasticity

et al. 2019

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M-type (KCNQ2/3) K + channels play dominant roles in regulation of active and passive neuronal discharge properties such as resting membrane potential, spike-frequency adaptation, and hyper-excitatory states. However, plasticity of M-channel expression and function in nongenetic forms of epileptogenesis are still not well understood. Using transgenic mice with an EGFP reporter to detect expression maps of KCNQ2 mRNA, we assayed hyperexcitability-induced alterations in KCNQ2 transcription across subregions of the hippocampus. Pilocarpine and pentylenetetrazol chemoconvulsant models of seizure induction were used, and brain tissue examined 48 hr later. We observed increases in KCNQ2 mRNA in CA1 and CA3 pyramidal neurons after chemoconvulsantinduced hyperexcitability at 48 hr, but no significant change was observed in dentate gyrus (DG) granule cells. Using chromogenic in situ hybridization assays, changes to KCNQ3 transcription were not detected after hyper-excitation challenge, but the results for KCNQ2 paralleled those using the KCNQ2-mRNA reporter mice. In mice 7 days after pilocarpine challenge, levels of KCNQ2 mRNA were similar in all regions to those from control mice. In brain-slice electrophysiology recordings, CA1 pyramidal neurons demonstrated increased M-current amplitudes 48 hr after hyperexcitability; however, there were no significant changes to DG granule cell M-current amplitude. Traumatic brain injury induced significantly greater KCNQ2 expression in the hippocampal hemisphere that was ipsilateral to the trauma. In vivo, after a secondary challenge with subconvulsant dose of pentylenetetrazole, control mice were susceptible to tonicclonic seizures, whereas mice administered the M-channel opener retigabine were protected from such seizures. This study demonstrates that increased excitatory activity promotes KCNQ2 upregulation in the hippocampus in a cell-type specific manner. Such novel ion channel expressional plasticity may serve as a compensatory mechanism after a hyperexcitable event, at least in the short term. The upregulation described could be potentially leveraged in anticonvulsant enhancement of KCNQ2 channels as therapeutic target for preventing onset of epileptogenic seizures.

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Section: Discussionsupporting

confidence: 94%

Section: Resultssupporting

confidence: 70%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Functional responses of the hippocampus to hyperexcitability depend on directed, neuron‐specific KCNQ2 K⁺ channel plasticity

et al. 2019

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Replacing the oxidation‐sensitive triaminoaryl chemotype of problematic K_V7 channel openers: Exploration of a nicotinamide scaffold

Wurm

Bartz

Schulig

et al. 2022

Archiv der Pharmazie

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K V 7 channel openers have proven their therapeutic value in the treatment of pain as well as epilepsy and, moreover, they hold the potential to expand into additional indications with unmet medical needs. However, the clinically validated but meanwhile discontinued K V 7 channel openers flupirtine and retigabine bear an oxidation-sensitive triaminoraryl scaffold, which is suspected of causing adverse drug reactions via the formation of quinoid oxidation products. Here, we report the design and synthesis of nicotinamide analogs and related compounds that remediate the liability in the chemical structure of flupirtine and retigabine. Optimization of a nicotinamide lead structure yielded analogs with excellent K V 7.2/3 opening activity, as evidenced by EC 50 values approaching the single-digit nanomolar range. On the other hand, weighted K V 7.2/3 opening activity data including inactive compounds allowed for the establishment of structure-activity relationships and a plausible binding mode hypothesis verified by docking and molecular dynamics simulations.channels are homo-or heterotetrameric, voltage-gated potassium channels expressed in various tissues, [1] whereby especially heterotetrameric neuronal K V 7 channels predominantly composed of K V 7.2 and K V 7.3 subunits are validated pharmacological targets. [2] In general, K V 7 activation induces hyperpolarization of cell membranes, through which the ion channels contribute to controlling neuronal excitability. By increasing the action potential threshold [3] and medium afterhyperpolarization while reducing spike frequency, [4] K V 7 channels act as a "brake" for hyperexcitability. [5] Moreover, their opening probability can be influenced by small-molecule ligands, [6] making them attractive therapeutic targets, particularly for a range of neurological diseases. [5] For example, the administration of K V 7 channel openers was recently discussed for the therapy of various forms of brain damage, including chronic stress-induced brain injury (CSBI) as well as traumatic brain injury (TBI), for which currently no pharmacotherapeutic treatment options exist. In both cases, animal models suggest that reducing the underlying neuronal hyperexcitability by enhancing K V 7-mediated potassium currents might offer a protective effect. Thus, K V 7 channel activation may be a novel therapeutic intervention

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Enhancement of intrinsic neuronal excitability‐mediated by a reduction in hyperpolarization‐activated cation current (I_h) in hippocampal CA1 neurons in a rat model of traumatic brain injury

et al. 2020

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Traumatic brain injury (TBI) is associated with epileptiform activity in the hippocampus; however, the underlying mechanisms have not been fully determined. The goal was to understand what changes take place in intrinsic neuronal physiology in the hippocampus after blunt force trauma to the cortex. In this context, hyperpolarization-activated cation current (I h) currents may have a critical role in modulating the neuronal intrinsic membrane excitability; therefore, its contribution to the TBI-induced hyperexcitability was assessed. In a model of TBI caused by controlled cortical impact (CCI), the intrinsic electrophysiological properties of pyramidal neurons were examined 1 week after TBI induction in rats. Whole-cell patch-clamp recordings were performed under current-and voltage-clamp conditions following ionotropic receptors blockade. Induction of TBI caused changes in the intrinsic excitability of pyramidal neurons, as shown by a significant increase and decrease in firing frequency and in the rheobase current, respectively (p < .05). The evoked firing rate and the action potential time to peak were also significantly increased and decreased, respectively (p < .05). In the TBI group, the amplitude of instantaneous and steadystate I h currents was both significantly smaller than those in the control group (p < .05). The I h current density was also significantly decreased (p < .001). Findings indicated that TBI led to an increase in the intrinsic excitability in CA1 pyramidal neurons and changes in I h current could be, in part, one of the underlying mechanisms involved in this hyperexcitability.

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Prevention of brain damage after traumatic brain injury by pharmacological enhancement of KCNQ (Kv7, “M-type”) K⁺ currents in neurons

Cited by 43 publications

References 129 publications

Functional responses of the hippocampus to hyperexcitability depend on directed, neuron‐specific KCNQ2 K⁺ channel plasticity

Functional responses of the hippocampus to hyperexcitability depend on directed, neuron‐specific KCNQ2 K⁺ channel plasticity

Replacing the oxidation‐sensitive triaminoaryl chemotype of problematic K_V7 channel openers: Exploration of a nicotinamide scaffold

Enhancement of intrinsic neuronal excitability‐mediated by a reduction in hyperpolarization‐activated cation current (I_h) in hippocampal CA1 neurons in a rat model of traumatic brain injury

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Prevention of brain damage after traumatic brain injury by pharmacological enhancement of KCNQ (Kv7, “M-type”) K+ currents in neurons

Cited by 43 publications

References 129 publications

Functional responses of the hippocampus to hyperexcitability depend on directed, neuron‐specific KCNQ2 K+ channel plasticity

Functional responses of the hippocampus to hyperexcitability depend on directed, neuron‐specific KCNQ2 K+ channel plasticity

Replacing the oxidation‐sensitive triaminoaryl chemotype of problematic KV7 channel openers: Exploration of a nicotinamide scaffold

Enhancement of intrinsic neuronal excitability‐mediated by a reduction in hyperpolarization‐activated cation current (Ih) in hippocampal CA1 neurons in a rat model of traumatic brain injury

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Prevention of brain damage after traumatic brain injury by pharmacological enhancement of KCNQ (Kv7, “M-type”) K⁺ currents in neurons

Functional responses of the hippocampus to hyperexcitability depend on directed, neuron‐specific KCNQ2 K⁺ channel plasticity

Functional responses of the hippocampus to hyperexcitability depend on directed, neuron‐specific KCNQ2 K⁺ channel plasticity

Replacing the oxidation‐sensitive triaminoaryl chemotype of problematic K_V7 channel openers: Exploration of a nicotinamide scaffold

Enhancement of intrinsic neuronal excitability‐mediated by a reduction in hyperpolarization‐activated cation current (I_h) in hippocampal CA1 neurons in a rat model of traumatic brain injury