[Ketamine: a neuropsychotropic drug with an innovative mechanism of action]. / La kétamine : un neuropsychotrope au mécanisme d'action innovant.

Ketamine, a non-competitive antagonist of the N-methyl-D-aspartate-glutamate receptor (R-NMDA), has a rapid (from 24 h post-dose) and prolonged (up to one week) antidepressant effect in treatment resistant depression and in rodent models of anxiety/depression. Arguments regarding its cellular and molecular mechanisms underlying its antidepressant activity mainly come from animal studies. However, debates still persist on the structural remodeling of frontocortical/hippocampal neurons and the role of excitatory/inhibitory neurotransmitters involved in its behavioral effect. Neurochemical and behavioral changes are maintained 24 h after administration of ketamine, well beyond its plasma elimination half-life. The glutamatergic pyramidal cells of the medial prefrontal cortex are primarily implicated in the therapeutic effects of ketamine. Advances in knowledge of the consequences of R-NMDA blockade allowed to specify the underlying mechanisms involving the activation of AMPA glutamate receptors, which triggers a cascade of intracellular events dependent on the mechanistic target of rapamycin, brain-derived neurotrophic factor, and synaptic protein synthesis facilitating synaptic plasticity (number of dendritic spines, synaptogenesis). This review focuses on abnormalities of neurotransmitter systems involved in major depressive disorders, their potential impact on neural circuitry and beneficial effects of ketamine. Recent preclinical data pave the way for future studies to better clarify the mechanism of action of fast-acting antidepressant drugs for the development of novel, more effective therapies.

Title: La kétamine : un neuropsychotrope au mécanisme d'action innovant. Abstract: La kétamine, un antagoniste non compétitif du récepteur N-méthyl-D-aspartate (R-NMDA) du glutamate, possède un effet antidépresseur rapide (dès 24 h post-dose) et prolongé (jusqu'à une semaine) dans la dépression résistante au traitement par des antidépresseurs « classiques ¼ et dans les modèles rongeurs d'anxiété/dépression. Les arguments concernant ses mécanismes cellulaires et moléculaires sous-tendant son activité antidépressive viennent principalement d'études animales. Des débats persistent cependant sur le remodelage structurel des neurones frontocorticaux/hippocampiques et sur le rôle des neurotransmetteurs excitateurs/inhibiteurs impliqués dans cet effet comportemental observé chez l'animal. Les modifications neurochimiques et comportementales se maintiennent 24 h après l'administration de la kétamine, bien au-delà de sa demi-vie d'élimination plasmatique. L'avancée des connaissances sur les conséquences du blocage du R-NMDA permet de préciser les mécanismes sous-jacents impliquant (i) l'activation des récepteurs AMPA du glutamate, qui déclenche une cascade d'évènements intracellulaires dépendants de la cible mécanistique de la rapamycine, (ii) le facteur neurotrophique dérivé du cerveau et (iii) la synthèse de protéines synaptiques facilitant la plasticité synaptique (nombre d'épines dendritiques, synaptogenèse). Les cellules pyramidales glutamatergiques du cortex préfrontal médian sont principalement impliquées dans les effets thérapeutiques de la kétamine. La présente revue se concentre sur les anomalies des systèmes de neurotransmetteurs associées aux troubles dépressifs caractérisés, leur impact potentiel sur les circuits neuronaux et les effets bénéfiques de la kétamine. Les résultats d'études précliniques récentes devraient aider à orienter les futures études pour mieux préciser le mécanisme d'action des antidépresseurs d'action rapide et permettre ainsi le développement de nouvelles thérapies plus efficaces.

Neuronal plasticity contributes to postictal death.

Repeated generalized tonic-clonic seizures (GTCSs) are the most critical risk factor for sudden unexpected death in epilepsy (SUDEP). GTCSs can cause fatal apnea. We investigated neuronal plasticity mechanisms that precipitate postictal apnea and seizure-induced death. Repeated seizures worsened behavior, precipitated apnea, and enlarged active neuronal circuits, recruiting more neurons in such brainstem nuclei as periaqueductal gray (PAG) and dorsal raphe, indicative of brainstem plasticity. Seizure-activated neurons are more excitable and have enhanced AMPA-mediated excitatory transmission after a seizure. Global deletion of the GluA1 subunit of AMPA receptors abolishes postictal apnea and seizure-induced death. Treatment with a drug that blocks Ca2+-permeable AMPA receptors also renders mice apnea-free with five-fold better survival than untreated mice. Repeated seizures traffic the GluA1 subunit-containing AMPA receptors to synapses, and blocking this mechanism decreases the probability of postictal apnea and seizure-induced death.

AMPA Receptor Encephalitis in a Patient With Metastatic Breast Cancer Receiving Palbociclib: A Case Report.

OBJECTIVE: To report a case of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor encephalitis (AMPARE) as a potential immune-mediated complication of palbociclib (a cyclin-dependent kinase 4/6 inhibitor). BACKGROUND: Medication-induced autoimmune encephalitis is an increasingly recognized entity. To date, cases have been reported with immune checkpoint inhibitors (ICIs), typically within 3 months and while cancer is responding to immunotherapy. RESULTS: A 55-year-old woman with metastatic breast cancer presented with new-onset neurologic symptoms. After diagnosis and treatment in 2008, she was in remission from 2010 to 2021. In April 2021, she developed metastatic recurrence. She started palbociclib in June 2021. PET scan in August 2021 showed improved metastases without new lesions. In September 2021, she developed encephalopathy, vertical nystagmus, and ataxia. Workup revealed AMPA-R antibodies. Palbociclib was stopped, and she received steroids, IVIg, and rituximab with marked improvement in her neurologic symptoms. DISCUSSION: AMPARE is a well-described paraneoplastic syndrome. However, it is now understood that paraneoplastic syndromes can be driven by immunomodulatory medications, namely ICIs. Although palbociclib primarily prevents tumor proliferation, emerging data suggest that it may also be immunomodulatory. Given that our patient's AMPARE developed shortly after initiation of palbociclib while her cancer was responding to therapy, we postulate that it may have been unmasked by palbociclib, similarly to what has been reported with ICIs.

A Class I HDAC Inhibitor Rescues Synaptic Damage and Neuron Loss in APP-Transfected Cells and APP/PS1 Mice through the GRIP1/AMPA Pathway.

As a neurodegenerative disease, Alzheimer's disease (AD) seriously affects the health of older people. Changes in synapses occur first over the course of the disease, perhaps even before the formation of Aß plaques. Histone deacetylase (HDAC) mediates the damage of Aß oligomers to dendritic spines. Therefore, we examined the relationship between HDAC activity and synaptic defects using an HDAC inhibitor (HDACI), BG45, in the human neuroblastoma SH-SY5Y cell line with stable overexpression of Swedish mutant APP (APPsw) and in APP/PS1 transgenic mice during this study. The cells were treated with 15 µM BG45 and the APP/PS1 mice were treated with 30 mg/kg BG45. We detected the levels of synapse-related proteins, HDACs, tau phosphorylation, and amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptors using Western blotting and immunohistochemistry. We also measured the expression of cytoskeletal proteins in the cell model. The mRNA levels of the glutamate ion receptor alginate subunit 2 (GRIK2), sodium voltage-gated channel beta subunit (SCN3B), synaptophysin (SYP), Grm2 (the gene encoding glutamate receptor subunit 2 (GluR2)), Grid2IP, glutamate receptor interacting protein 1 (GRIP1), and GRIP2 were detected to explore the effects of the HDACI on regulating the expression of synaptic proteins and AMPA receptors. According to our studies, the expressions of HDAC1, HDAC2, and HDAC3 were increased, which were accompanied by the downregulation of the synapse-related proteins SYP, postsynaptic dendritic protein (PSD-95), and spinophilin as early as 24 h after transfection with the APPsw gene. BG45 upregulated the expression of synapse-related proteins and repaired cytoskeletal damage. In vivo, BG45 alleviated the apoptosis-mediated loss of hippocampal neurons, upregulated synapse-related proteins, reduced Aß deposition and phosphorylation of tau, and increased the levels of the synapse-related genes GRIK2, SCN3B, SYP, Grm2, and Grid2IP. BG45 increased the expression of the AMPA receptor subunits GluA1, GluA2, and GluA3 on APPsw-transfected cells and increased GRIP1 and GRIP2 expression and AMPA receptor phosphorylation in vivo. Based on these results, HDACs are involved in the early process of synaptic defects in AD models, and BG45 may rescue synaptic damage and the loss of hippocampal neurons by specifically inhibiting HDAC1, HDAC2, and HDAC3, thereby modulating AMPA receptor transduction, increasing synapse-related gene expression, and finally enhancing the function of excitatory synapses. BG45 may be considered a potential drug for the treatment of early AD in further studies.

Effectiveness of perampanel in managing chronic pain caused by the complex regional pain syndrome: A case report.

RATIONALE: The α-amino-3-hydroxy-5-methy-4-isoxazole propionate (AMPA) receptor plays a critical role in the development and persistence of pain, and AMPA receptor antagonists are considered possible therapeutic targets for controlling pain. This report describes a patient with complex regional pain syndrome (CRPS) type I in the right lower leg and foot who responded well to perampanel, an AMPA receptor antagonist, for managing the chronic pain. PATIENT CONCERN: A 61-year-old woman complained of pain in her right lower leg and foot over a period of 7 year (numeric rating scale: 8) due to CRPS type I. DIAGNOSIS: CRPS type 1. INTERVENTIONS: Despite the combination of 300 mg pregabalin, 225 mg/1950 mg tramadol/acetaminophen, and 10 mg nortriptyline per day, her right lower leg and foot were nearly disabled due to the severity of the pain. High-dose prednisolone was found to be ineffective. Then, perampanel (4 mg; 2 mg twice) was administered to this patient daily. OUTCOMES: The day after treatment with perampanel, her pain completely disappeared. Additionally, at day 7 and 1 month follow-up, she reported no pain in the right lower leg and foot. Moreover, no adverse effects were reported after the application of perampanel. LESSONS: These results suggest that perampanel may potentially be used to treat centralized pain.

AMPA Receptors as Therapeutic Targets for Neurological Disorders.

Almost every neurological disease directly or indirectly affects synapse function in the brain. However, these diseases alter synapses through different mechanisms, ultimately resulting in altered synaptic transmission and/or plasticity. Glutamate is the major neurotransmitter that mediates excitatory synaptic transmission in the brain through activation of alpha-amino-3-hydroxy-5-methyl-4-isoxazole-propionate (AMPA) receptors. These receptors have therefore been identified as a target for the development of therapeutic treatments for neurological disorders including epilepsy, neurodegenerative diseases, autism, and drug addiction. The fact that AMPA receptors play a dominant role throughout the brain raises the significant challenge of selectively targeting only those regions affected by disease, and clinical trials have raised doubt regarding the feasibility of specifically targeting AMPA receptors for new therapeutic options. Benzamide compounds that act as positive allosteric AMPA receptor modulators, known as AMPAkines, can act on specific brain regions and were initially proposed to revolutionize the treatment of cognitive deficits associated with neurological disorders. Their therapeutic potential has since declined due to inconsistent results in clinical trials. However, recent advances in basic biomedical research are significantly increasing our knowledge of AMPA receptor structure, binding sites, and interactions with auxiliary proteins. In particular, the large complex of postsynaptic proteins that interact with AMPA receptor subunits have been shown to control AMPA receptor insertion, location, pharmacology, synaptic transmission, and plasticity. These proteins are now being considered as alternative therapeutic target sites for modulating AMPA receptors in neurological disorders.

Glutamate modulators as novel interventions for mood disorders.

UNLABELLED: Recent evidence suggests that critical molecules in neurotrophic signaling cascades are long-term targets for currently available monoaminergic antidepressants. As chronic and severe mood disorders are characterized by impairments in neuronal resilience, pharmacological strategies that subserve a neuroprotective function might alter disorder pathophysiology and modify disease progression. Several promising approaches involve modulation of the glutamate neurotransmitter system, via post-synaptic receptor blockade or potentiation and presynaptic vesicular release inhibition. A focused review of the extant scientific literature was conducted, with a discussion of 3 compounds or classes of drugs currently undergoing clinical investigation: ketamine, riluzole, and AMPA receptor potentiators. Recent investigations in mood disordered patients suggest that the NMDA receptor antagonist ketamine might demonstrate rapid antidepressant properties. Riluzole has been shown to reverse glutamate-mediated impairments in neuronal plasticity and to stimulate the synthesis of brain derived neurotrophic factor. Open-label trials in treatment-resistant depression have yielded promising results. Likewise, AMPA receptor potentiators favorably impact neurotrophic factors as well as enhance cognition. CONCLUSIONS: Pharmacological approaches that modulate components of the glutamate system offer novel targets for severe, recurrent mood disorders. Controlled studies are necessary.

Glutamate modulators as novel interventions for mood disorders

Recentes evidências sugerem que as moléculas críticas nas cascatas de sinalizacão neurotrófica são alvos de longo prazo dos antidepressivos monoaminérgicos disponíveis atualmente. Na medida em que transtornos graves e crônicos são caracterizados por deficiências na resiliência neuronal, estratégias farmacológicas que sejam úteis para uma funcão neuroprotetora talvez possam alterar a fisiopatologia e modificar a progressão da doenca. Vários enfoques promissores envolvem a modulacão do sistema neurotransmissor do glutamato, via bloqueio ou potencializacão do receptor pós-sináptico e inibicão da liberacão vesicular pré-sináptica. Foi realizada uma revisão focada da literatura científica existente, com a discussão de três compostos ou classes de drogas que estão atualmente sob investigacão clínica: a ketamina, o riluzol e os potencializadores de receptores de AMPA. DISCUSSAO: Estudos recentes com pacientes com transtornos de humor sugerem que a ketamina, um antagonista do receptor NMDA, poderia ter demonstrado propriedades antidepressivas rápidas. O riluzol demonstrou reverter deficiências mediadas pelo glutamato na plasticidade neuronal e estimular a síntese de fatores neurotróficos derivados do cérebro. Ensaios abertos com depressão resistente ao tratamento produziram resultados promissores. Da mesma forma, os potencializadores de receptores de AMPA impactam favoravelmente os fatores neurotróficos, assim como melhoram a cognicão. CONCLUSÕES: Enfoques farmacológicos que modulam os componentes do sistema de glutamato oferecem novos alvos para transtornos de humor recorrentes e graves. São necessários estudos controlados.

Activation of AMPA receptors in the cerebral cortex may be protective against migraine headache [abstract]

The pathogenesis of migraine involves a spreading depression of neurons in the cerebral cortex resulting from over-excitation by released neurotransmitters or electrolytes. Glutamic acid is the most common excitatory neurotransmitter in the brain and spinal cord of mammals. Analogues of glutamic acid including AMPA (DL-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid) and NMDA (N-methyl-D-asparatic acid) act on different receptors to depolarize the neurons of the cerebral cortex. Previous work has shown that evoked electrical potentials recover from the effects of NMDA on this neuronal network, suggesting a form of neuronal desensitization or network adaption. We have extended these observations by examining the effects of AMPA in the cerebral cortex, the interactions between AMPA and NMDA and the interactions between AMPA and spreading depression. Male Sprague-Dawley rats were anaesthetized with urethane and potentials evoked at the cortical surface by electrical stimulation of the contralateral forepaw. The compounds were applied topically to the cortex by a cortical cup. NMDA at 0.05-0.25mM caused a concentration-dependent decrease in the amplitude of the potentials, with the highest concentration always abolishing them. AMPA at 0.05mM did not affect the evoked potentials when applied alone, but when 0.25mM NMDA was preceeded by an application of AMPA, the latter prevented the NMDA effects in a concentration-dependent manner. Such AMPA-NMDA interactions were inhibited by CNQX (6-cyano-7-nmitroquinoxalinne-2, 3-dione, an antagonist of AMPA) and ehanced by cyclothiadize (which prevents AMPA desensitization). Topical application of AMPA, (0.5mM) prevented the electrophysiological manifestation of spreading depression in the cerebral cortex. Chlormethiazole, a GABA-mimetic drug that is known to prevent epileptic seizures, at 0.2-2mM, was not effective in preventing the spreading depression. These results suggest that, in the rate cerebral cortex, activation of the AMPA receptor (a glutamic acid receptor subtype) can induce a loss of neuronal response to activation of another glumatic acid receptor subtype, the NMDA receptor. Also, activation of the AMPA receptor in the cerebral cortex seems to have a neuroprotective role against the spreading depression that has been implicated in migraine. (AU)