High-Dose Benzodiazepines Positively Modulate GABAA Receptors via a Flumazenil-Insensitive Mechanism.

Benzodiazepines (BZDs) produce versatile pharmacological actions through positive modulation of GABAA receptors (GABAARs). A previous study has demonstrated that high concentrations of diazepam potentiate GABA currents on the α1ß2γ2 and α1ß2 GABAARs in a flumazenil-insensitive manner. In this study, the high-concentration effects of BZDs and their sensitivity to flumazenil were determined on synaptic (α1ß2γ2, α2ß2γ2, α5ß2γ2) and extra-synaptic (α4ß2δ) GABAARs using the voltage-clamp electrophysiology technique. The in vivo evaluation of flumazenil-insensitive BZD effects was conducted in mice via the loss of righting reflex (LORR) test. Diazepam induced biphasic potentiation on the α1ß2γ2, α2ß2γ2 and α5ß2γ2 GABAARs, but did not affect the α4ß2δ receptor. In contrast to the nanomolar component of potentiation, the second potentiation elicited by micromolar diazepam was insensitive to flumazenil. Midazolam, clonazepam, and lorazepam at 200 µM exhibited similar flumazenil-insensitive effects on the α1ß2γ2, α2ß2γ2 and α5ß2γ2 receptors, whereas the potentiation induced by 200 µM zolpidem or triazolam was abolished by flumazenil. Both the GABAAR antagonist pentylenetetrazol and Fa173, a proposed transmembrane site antagonist, abolished the potentiation induced by 200 µM diazepam. Consistent with the in vitro results, flumazenil antagonized the zolpidem-induced LORR, but not that induced by diazepam or midazolam. Pentylenetetrazol and Fa173 antagonized the diazepam-induced LORR. These findings support the existence of non-classical BZD binding sites on certain GABAAR subtypes and indicate that the flumazenil-insensitive effects depend on the chemical structures of BZD ligands.

HCN channel antagonist ZD7288 ameliorates neuropathic pain and associated depression.

Chronic neuropathic pain has demonstrated that coexisting psychiatric disorders are associated with disability and poorer treatment outcomes. Hyperpolarization-activated cyclic nucleotide-gated (HCN, Ih) channels play a major role in pain via hyperexcitability and facilitation of ectopic firing in neurons. Neuronal hyperexcitability contributes to pain maintenance and anxiety/depression. GABA-mediated inhibitory postsynaptic neurotransmission in the brain is impaired in the pathophysiology of chronic neuropathic pain with comorbidity mood disorders. Currently, interaction of HCN channels and GABAergic synaptic transmission inhibition in neuropathic pain and the associated comorbidity anxiety/depression mechanism remains relatively unknown. To address this, the HCN channel inhibitor, ZD7288, was administrated to Wistar Kyoto (WKY) rats after spared nerve injury (SNI). Our findings show that intracerebroventricular injection of ZD7288 concurrently attenuates co-existing nociceptive and depression-like behaviors, and increases glutamicacid decarboxylase (GAD67/65) expression and GABA levels in the hippocampus and thalamus with High-performance liquid chromatography technique. It suggests that inhibition of HCN channels is likely to decrease the hyperexcitability of neurons in rat SNI and improve the level of GABA. Further, HCN channel may offer a new strategy to alleviate both neuropathic pain and comorbidity for depression.

C101, a novel 4-amino-piperidine derivative selectively blocks N-type calcium channels.

N-type Ca2+ channels located on presynaptic nerve terminals regulate neurotransmitter release, including that from the spinal terminations of primary afferent nociceptors. Pharmacological and ion-channel gene knockdown approaches in animals have revealed N-type Ca2+ channels to be particularly attractive molecular targets for the discovery and development of new analgesic drugs. In recent years, some non-peptide small molecular N-type Ca2+ channel blockers have been reported. However, low selectivity and some side effects limit their further development. To overcome these disadvantages, some new compounds were designed and synthesized in our institute by optimizing the 4-amino-piperidine template. C101, one of these compounds, was demonstrated to block N-type Ca2+ channels with higher selectivity. It was found that C101 produced concentration-dependent inhibition on N-type Ca2+ channels expressed in Xenopus oocytes with an IC50 is 2.2+/-0.6 microM. The current-voltage relationship was not altered after 2-min exposure to C101. However, the steady-state inactivation relationship curve was shifted to more negative potentials for channels. Therefore, it seemed that C101 blocks the inactivated channel. C101 did not present any remarkable effects on voltage-gated potassium, sodium channels in cultured rat hippocampal neurons, and L-, P/Q-, R-type calcium channels and HERG channels expressed in Xenopus oocytes. The results suggested that C101 was a high selective blocker targeting N-type Ca2+ channels, and may have a potential to be developed as a novel analgesic agent.