Excitatory Transmission Research Articles

Function and Breakdown of the Neuron-Glia Dual-Layer Super-Network

Glial cells appear to have the capacity of coding information. Neuronal and glial circuits form a loosely coupled dual-layer super network within the brain. Glial cells react with the excitatory transmitter glutamate released from synapses of neurons and, in turn, release additional glutamate. Thus, they effectively function as excitatory signal amplifiers, with the gain of amplification depending on their cytosolic pH. Activation of metabotropic glutamate receptors in neurons is largely influenced by the state of glial cells. Depending on the state of our mind, an experience can become a lasting memory or fade away. The pH of glial cells at the time of the experience could play a pivotal role in memory formation. Glial function is also susceptible to plasticity. First-time exposure to a brief period of brain hyperactivity results in an acute breakdown of the inter-cellular network of glial cells. Therefore, artificial control of the glial state and glial plasticity may provide a new preventative strategy to manage dementia and epilepsy.

Gating and modulation of a hetero-octameric AMPA glutamate receptor.

AMPA receptors (AMPARs) mediate the majority of excitatory transmission in the brain and enable the synaptic plasticity that underlies learning1. A diverse array of AMPAR signalling complexes are established by receptor auxiliary subunits, which associate with the AMPAR in various combinations to modulate trafficking, gating and synaptic strength2. However, their mechanisms of action are poorly understood. Here we determine cryo-electron microscopy structures of the heteromeric GluA1-GluA2 receptor assembled with both TARP-γ8 and CNIH2, the predominant AMPAR complex in the forebrain, in both resting and active states. Two TARP-γ8 and two CNIH2 subunits insert at distinct sites beneath the ligand-binding domains of the receptor, with site-specific lipids shaping each interaction and affecting the gating regulation of the AMPARs. Activation of the receptor leads to asymmetry between GluA1 and GluA2 along the ion conduction path and an outward expansion of the channel triggers counter-rotations of both auxiliary subunit pairs, promoting the active-state conformation. In addition, both TARP-γ8 and CNIH2 pivot towards the pore exit upon activation, extending their reach for cytoplasmic receptor elements. CNIH2 achieves this through its uniquely extended M2 helix, which has transformed this endoplasmic reticulum-export factor into a powerful AMPAR modulator that is capable of providing hippocampal pyramidal neurons with their integrative synaptic properties.

Exposure to Prenatal Stress Is Associated With an Excitatory/Inhibitory Imbalance in Rat Prefrontal Cortex and Amygdala and an Increased Risk for Emotional Dysregulation.

Epidemiological studies have shown that environmental insults and maternal stress during pregnancy increase the risk of several psychiatric disorders in the offspring. Converging lines of evidence from humans, as well as from rodent models, suggest that prenatal stress (PNS) interferes with fetal development, ultimately determining changes in brain maturation and function that may lead to the onset of neuropsychiatric disorders. From a molecular standpoint, transcriptional alterations are thought to play a major role in this context and may contribute to the behavioral phenotype by shifting the expression of genes related to excitatory and inhibitory (E/I) transmission balance. Nevertheless, the exact neurophysiological mechanisms underlying the enhanced vulnerability to psychopathology following PNS exposure are not well understood. In the present study, we used a model of maternal stress in rats to investigate the distal effects of PNS on the expression of genes related to glutamatergic and GABAergic neurotransmissions. We inspected two critical brain regions involved in emotion regulation, namely, the prefrontal cortex (PFC) and the amygdala (AMY), which we show to relate with the mild behavioral effects detected in adult rat offspring. We observed that PNS exposure promotes E/I imbalance in the PFC of adult males only, by dysregulating the expression of glutamatergic-related genes. Moreover, such an effect is accompanied by increased expression of the activity-dependent synaptic modulator gene Npas4 specifically in the PFC parvalbumin (PV)-positive interneurons, suggesting an altered regulation of synapse formation promoting higher PV-dependent inhibitory transmission and increased overall circuit inhibition in the PFC of males. In the AMY, PNS more evidently affects the transcription of GABAergic-related genes, shifting the balance toward inhibition. Collectively, our findings suggest that the E/I dysregulation of the PFC-to-AMY transmission may be a long-term signature of PNS and may contribute to increase the risk for mood disorder upon further stress.

Decreased Resting-State Functional Connectivity of Periaqueductal Gray in Temporal Lobe Epilepsy Comorbid With Migraine.

Objective: Patients with temporal lobe epilepsy (TLE) are at high risk for having a comorbid condition of migraine, and these two common diseases are proposed to have some shared pathophysiological mechanisms. Our recent study indicated the dysfunction of periaqueductal gray (PAG), a key pain-modulating structure, contributes to the development of pain hypersensitivity and epileptogenesis in epilepsy. This study is to investigate the functional connectivity of PAG network in epilepsy comorbid with migraine.Methods: Thirty-two patients with TLE, including 16 epilepsy patients without migraine (EwoM) and 16 epilepsy patients with comorbid migraine (EwM), and 14 matched healthy controls (HCs) were recruited and underwent resting functional magnetic resonance imaging (fMRI) scans to measure the resting-state functional connectivity (RsFC) of PAG network. The frequency and severity of migraine attacks were assessed using the Migraine Disability Assessment Questionnaire (MIDAS) and Visual Analog Scale/Score (VAS). In animal experiments, FluoroGold (FG), a retrograde tracing agent, was injected into PPN and its fluorescence detected in vlPAG to trace the neuronal projection from vlPAG to PPN. FG traced neuron number was used to evaluate the neural transmission activity of vlPAG-PPN pathway. The data were processed and analyzed using DPARSF and SPSS17.0 software. Based on the RsFC finding, the excitatory transmission of PAG and the associated brain structure was studied via retrograde tracing in combination with immunohistochemical labeling of excitatory neurons.Results: Compared to HCs group, the RsFC between PAG and the left pedunculopontine nucleus (PPN), between PAG and the corpus callosum (CC), was decreased both in EwoM and EwM group, while the RsFC between PAG and the right PPN was increased only in EwoM group but not in EwM group. Compared to EwoM group, the RsFC between PAG and the right PPN was decreased in EwM group. Furthermore, the RsFC between PAG and PPN was negatively correlated with the frequency and severity of migraine attacks. In animal study, a seizure stimulation induced excitatory transmission from PAG to PPN was decreased in rats with chronic epilepsy as compared to that in normal control rats.Conclusion: The comorbidity of epilepsy and migraine is associated with the decreased RsFC between PAG and PPN.

Frontal cortex genetic ablation of metabotropic glutamate receptor subtype 3 (mGlu3) impairs postsynaptic plasticity and modulates affective behaviors.

Clinical and translational studies suggest that prefrontal cortex (PFC) dysregulation is a hallmark feature of several affective disorders. Thus, investigating the mechanisms involved in the regulation of PFC function and synaptic plasticity could aid in developing new medications. In recent years, the mGlu2 and mGlu3 subtypes of metabotropic glutamate (mGlu) receptors have emerged as exciting potential targets for the treatment of affective disorders, as mGlu2/3 antagonists exert antidepressant-like effects across many rodent models. Several recent studies suggest that presynaptic mGlu2 receptors may contribute to these effects by regulating excitatory transmission at synapses from the thalamus to the PFC. Interestingly, we found that mGlu3 receptors also inhibit excitatory drive to the PFC but act by inducing long-term depression (LTD) at amygdala-PFC synapses. It remains unclear, however, whether blockade of presynaptic, postsynaptic, or glial mGlu3 receptors contribute to long-term effects on PFC circuit function and antidepressant-like effects of mGlu2/3 antagonists. To address these outstanding questions, we leveraged transgenic Grm3fl/fl mice and viral-mediated gene transfer to genetically ablate mGlu3 receptors from pyramidal cells in the frontal cortex of adult mice of all sexes. Consistent with a role for mGlu3 in PFC pyramidal cells, mGlu3-dependent amygdala-cortical LTD was eliminated following mGlu3 receptor knockdown. Furthermore, knockdown mice displayed a modest, task-specific anxiolytic phenotype and decreased passive coping behaviors. These studies reveal that postsynaptic mGlu3 receptors are critical for mGlu3-dependent LTD and provide convergent genetic evidence suggesting that modulating cortical mGlu3 receptors may provide a promising new approach for the treatment of mood disorders.

Fast synaptic excitatory neurotransmission in the human submucosal plexus.

Acetylcholine is the main excitatory neurotransmitter in the enteric nervous system (ENS) in all animal models examined so far. However, data for the human ENS is scarce. We used neuroimaging using voltage and calcium dyes, Ussing chamber, and immunohistochemistry to study fast synaptic neurotransmission in submucosal plexus neurons of the human gut. Electrical stimulation of intraganglionic fiber tracts led to fast excitatory postsynaptic potentials (fEPSPs) in 29 submucosal neurons which were all blocked by the nicotinic antagonist hexamethonium. The nicotinic agonist DMPP mimicked the effects of electrical stimulation and had excitatory effects on 56 of 73 neurons. The unselective NMDA antagonist MK-801 blocked fEPSPs in 14 out of 22 neurons as well as nicotine evoked spike discharge. In contrast, the application of NMDA showed only weak effects on excitability or calcium transients. This agreed with the finding that the specific NMDA antagonist D-APV reduced fEPSPs in only 1 out of 40 neurons. Application of AMPA or kainite had no effect in 41 neurons or evoked spike discharge in only one out of 41 neurons, respectively. Immunohistochemistry showed that 98.7±2.4% of all submucosal neurons (n=6 preparations, 1003 neurons) stained positive for the nicotinic receptor (α1 , α2 or α3 -subunit). Hexamethonium (200µM) reduced nerve-evoked chloride secretion by 34.3±18.6% (n=14 patients), whereas D-APV had no effect. Acetylcholine is the most important mediator of fast excitatory postsynaptic transmission in human submucous plexus neurons whereas glutamatergic fEPSPs were rarely encountered.

SnapShot: Neuronal dysfunction in inflammation

Neuronal function relies on tightly controlled cytoskeleton transport with adaptive cargo trafficking as prerequisite for synaptic transmission. During inflammation in multiple sclerosis (MS) and experimental autoimmune encephalomyelitis (EAE), axonal transport efficiency declines, followed by neurodegeneration. Furthermore, neuroinflammation causes an imbalance between excitatory and inhibitory transmission, triggering synaptic dysfunction and loss. Recent data suggest that neuronal transport and synaptic deficits during neuroinflammation are functionally interconnected. To view this SnapShot, open or download the PDF.

Diminished inhibitory efficacy of GABA on PVN neurons in AngII‐salt hypertension reflects a KCC2‐independent increase of intracellular Cl‐ concentration

The hypothalamic PVN receives glutamatergic excitation from sodium and AngII sensing regions of the forebrain along with dense GABAergic inhibition from the surrounding peri-nuclear zone (PNZ). Previously, we found that synaptic glutamate release in PVN enhances GABA inhibition, but whether forebrain inputs can do so in the setting of hypertension (HTN) is unknown. Studies indicate that a high salt diet alone does not raise mean arterial pressure (MAP), while AngII treatment raises MAP in proportion to the level of salt intake. This suggests that whereas excitatory inputs to PVN driven by high salt intake alone cannot overcome PVN GABA inhibition, AngII driven inputs can. The notion that GABA inhibition of PVN is strengthened forebrain inputs in AngII-salt HTN is contrary to a prior report that GABA inhibition in AngII-salt HTN is reduced. To reconcile these seemingly disparate findings, we compared mechanisms regulating PVN GABA inhibition in mice consuming a normal salt (0.4% NaCl) diet (NSD), a high salt (4% NaCl) diet (HSD) or a HSD with AngII (600 ng/kg/min, s.c.) infusion (AngII-salt HTN). Using gramicidin perforated patch recordings, we determined that the GABA equilibrium potential (EGABA) of PVN neurons was not different between NSD (-67.2 ± 6.3 mV, n=3 cells) and HSD (-53.7 ± 15.6 mV, n=4 cells) mice, but was significantly depolarized in mice with AngII-salt HTN (-32.9 ± 8.8 mV, n=6 cells)(P=0.0033). This indicates that in AngII-salt HTN the inhibitory effect of GABA on PVN neurons decreases as [Cl-]i increases. Normally, [Cl-]i is held low by activities of KCC2 and NKCC1, which promote neuronal Cl- efflux and influx, respectively. In brain slices, KCC2 inhibition (VU0463271, 10 µM) rapidly depolarized PVN EGABA, consistent with blunting of GABA inhibition. Accordingly, PVN inhibition of KCC2 (VU0463271, 100 pmol, 25 nL) in vivo increased renal SNA, suggesting GABA was switched from an inhibitory to an excitatory transmitter. Consistent with this, PVN GABA-AR activation (muscimol, 50 pmol, 25 nL) during KCC2 inhibition increased renal SNA. Thus, KCC2 appears critical for maintaining low [Cl-]i and a hyperpolarized EGABA in PVN. In light of this, it would seem likely that elevated PVN [Cl-]i in AngII-salt HTN reflects a relative loss of KCC2 Cl- efflux. To investigate this, western blot analysis of PVN punches was performed and revealed that expression of KCC2 and NKCC1 was increased and decreased, respectively, both in mice consuming a HSD alone and mice with AngII-salt HTN. These changes were unexpected as they are predicted to drive [Cl-]i low, not high. Therefore, expression changes appear aimed at buffering elevated [Cl-]i caused by an alternative mechanism, possibly excess Cl- influx through GABA-AR, reflecting increased, not decreased, GABA release in AngII-salt HTN. Similar expression changes in HSD mice suggests that high salt intake generates a permissive state of Cl- ionic plasticity that blunts PVN GABA inhibition and facilitates AngII-salt HTN.

CIH Enhances Glutamatergic Transmission in Median Preoptic Nucleus

Studies have shown that the median preoptic nucleus (MnPO) contributes to hypertension associated with chronic intermittent hypoxia (CIH), a model of the hypoxemia associated with sleep apnea. Virally mediated lesions of MnPO neurons prevent the development of a sustained hypertension associated with CIH. To gain more insight into the properties of excitatory transmission to MnPO neurons develops in CIH, whole cell patch clamp recordings were from MnPO neurons brain slices from rats exposed to 7 days of CIH (6 minute cycles; 3 minutes of 21% oxygen room air pumped in, 90 seconds of nitrogen pumped in to lower the chamber O2 to 10% oxygen, and then 90 seconds of maintenance at 10% oxygen) for 8 h during the light phase or were normoxic controls. Slices were perfused with oxygenates artificial cerebrospinal fluid and the MnPO was visually identified. Miniature excitatory postsynaptic currents (mEPSCs) were recorded in the presences of 25 µm SR95531 (GABAA antagonist) and 1 µm TTX (block Na+ channel-mediated action potentials) using a conventional whole cell patch clamp configuration. The mEPSCs were collected over a 4 min period and amplitude and frequency were compared between cells obtained from slice prepared from normoxic control rats (NORM) or rats exposed to CIH. CIH was associated with a significant increase in mean amplitude (CIH 17.15 ± 0.65 pA, n=19 cells; NORM (15.6 ± 0.6 pA; n=18 cells, P <0.05). Similarly, mean frequency was significantly elevated after CIH (CIH 4.05 ± 0.5 Hz, n=19 vs NORM 2.56 ± 0.37 Hz, n=18; p<0.05) and associated with a significant leftward shift in the cumulative probability of inter event intervals. The results suggest that CIH simultaneously increases enhances spontaneous presynaptic neurotransmitter release while also increasing postsynaptic responsiveness in MnPO. These presynaptic and postsynaptic changes in MnPO that are associated with CIH may represent mechanism contributing to CIH hypertension.

GluN2B‐containing NMDA Receptors on Sst‐interneurons act as Initial Cellular Trigger for Antidepressant Actions of Ketamine

A single subanesthetic dose of ketamine exerts rapid antidepressant-like effects via rapid glutamate efflux, activation of mTORC1 signaling, and enhanced synaptic transmission in the medial prefrontal cortex (mPFC); however, the initial cellular trigger for these synaptic and behavioral actions of ketamine still remains unclear. Here, we used electrophysiology, biochemistry, molecular biology and behavioral approaches to determine the baseline sex differences in behavior after GluN2B conditional deletion from Sst-interneurons, and effect of ketamine on chronic unpredictable stress (CUS)-induced behavioral deficits, activation of mTOR signaling cascade and changes in synaptic transmission in male and female GluN2Bfl/fl (WT) and Sst-creGluN2Bfl/fl mice (KO) mice. Acute treatment of ketamine reduces NMDA-induced burst firing of Sst-interneurons ex vivo in mPFC. Deletion of GluN2B from Sst-GABAergic interneurons in the KO produced sexually dimorphic changes in synaptic transmission and behavior. Consistent with the disinhibition hypothesis, ketamine reduces inhibitory, but enhances excitatory transmission of layer V pyramidal neurons of mPFC and reverses CUS-induced behavioral deficits only in WT, but not KO, mice. Preliminary data demonstrate that deletion of GluN2B from Sst-interneurons blocks ketamine-induced activation of mTOR signaling cascade. Our results demonstrate that Sst-interneurons are an initial cellular trigger for synaptic and behavioral actions of ketamine. Consistent with the disinhibition hypothesis, ketamine actions are mediated by GluN2B-NMDARs on Sst-interneurons via disinhibition of pyramidal neurons, activation of mTOR signaling, and enhanced synaptic function in mPFC.

Increased immunoreactivity of glutamate receptors, neuronal nuclear protein and glial fibrillary acidic protein in the hippocampus of epileptic rats with fast ripple activity.

Epilepsy is a neurological disorder in which an imbalance between excitatory and inhibitory transmission is observed. Glutamate is the principal excitatory neurotransmitter that acts through ionic and metabotropic receptors; both types of receptors are involved in temporal lobe epilepsy (TLE). High frequency oscillations called fast ripples (FR, 250-600Hz) have been observed, particularly in the hippocampus, and they are involved in epileptogenesis. The present study analyzed the immunoreactivity of the principal glutamate receptors associated with epilepsy in epileptic animals with FR activity. Male Swiss-Wistar rats (210-250 gr) were injected with pilocarpine (2.4mg/2µl) and were video monitored (24/7) until the appearance of spontaneous and recurrent seizures. Then, a deep microelectrode implantation surgery was performed in the DG, CA3 and CA1 regions, and FR activity was observed 1-, 2-, 3-, 7-, and 14-day postsurgery. The animals were sacrificed on day 15, and fluorescence immunohistochemistry was carried out in the hippocampus for the α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA), N-methyl-D-aspartate (NMDA) and mGlu-R5 glutamate receptors as well as Neuronal Nuclear Protein (NeuN) and Glial Fibrillary Acidic Protein (GFAP). An increase in the immunoreactivity for the three receptors was found. However, the AMPA receptor showed an increase in the three regions analyzed (i.e., DG, CA1 and CA3). The findings showed a decrease of NeuN in the DG and an increase of GFAP. These results suggest an important role of glutamate receptors in the hippocampus of epileptic rats with FR activity.

Altered excitatory transmission in striatal neurons after chronic ethanol consumption in selectively bred crossed high alcohol-preferring mice

Genetic predisposition to heavy drinking is a risk factor for alcohol misuse. We used selectively bred crossed high alcohol-preferring (cHAP) mice to study sex differences in alcohol drinking and its effect on glutamatergic activity in dorsolateral (DLS) and dorsomedial (DMS) striatum. We performed whole-cell patch-clamp recording in neurons from male and female cHAP mice with 5-week alcohol drinking history and alcohol-naïve controls. In DMS, alcohol-naïve males' neurons displayed lower cell capacitance and higher membrane resistance than females’ neurons, both effects reversed by drinking. Conversely, in DLS neurons, drinking history increased capacitance only in males and changed membrane resistance only in females. Altered biophysical membrane properties were accompanied by disrupted glutamatergic transmission. Drinking history increased spontaneous excitatory postsynaptic current (sEPSC) amplitude in DMS and frequency in DLS female neurons, compared to alcohol-naïve females, without effect in males. Acute ethanol differentially impacted DMS and DLS neurons by sex and drinking history. In DMS, acute alcohol significantly increased sEPSC frequency only in neurons from alcohol-naïve females, an effect that disappeared after drinking history. In DLS, acute alcohol had opposing effects in males and females based on drinking history. Estrous cycle also impacted DMS and DLS neurons differently: sEPSC amplitudes were higher in DMS cells from drinking history than alcohol-naïve females, whereas estrous cycle, not drinking history, modified DLS firing rate. Our data show sex differences in cHAP ethanol consumption and neurophysiology, suggesting differential dysregulation of glutamatergic drive onto DMS and DLS after chronic ethanol consumption.

Rapid recycling of glutamate transporters on the astroglial surface.

Glutamate uptake by astroglial transporters confines excitatory transmission to the synaptic cleft. The efficiency of this mechanism depends on the transporter dynamics in the astrocyte membrane, which remains poorly understood. Here, we visualise the main glial glutamate transporter GLT1 by generating its pH-sensitive fluorescent analogue, GLT1-SEP. Fluorescence recovery after photobleaching-based imaging shows that 70-75% of GLT1-SEP dwell on the surface of rat brain astroglia, recycling with a lifetime of ~22 s. Genetic deletion of the C-terminus accelerates GLT1-SEP membrane turnover while disrupting its surface pattern, as revealed by single-molecule localisation microscopy. Excitatory activity boosts surface mobility of GLT1-SEP, involving its C-terminus, metabotropic glutamate receptors, intracellular Ca2+, and calcineurin-phosphatase activity, but not the broad-range kinase activity. The results suggest that membrane turnover, rather than lateral diffusion, is the main 'redeployment' route for the immobile fraction (20-30%) of surface-expressed GLT1. This finding reveals an important mechanism helping to control extrasynaptic escape of glutamate.

Chronic Blockade of NMDAR Subunit 2A in the Hypothalamic Paraventricular Nucleus Alleviates Hypertension Through Suppression of MEK/ERK/CREB Pathway

N-methyl-D-aspartate Receptor (NMDAR) in the hypothalamic paraventricular nucleus (PVN) plays critical roles in regulating sympathetic outflow. Studies showed that acute application of the antagonists of NMDAR or its subunits would reduce sympathetic nerve discharges. However, little is known about the effect of long-term management of NMDAR in hypertensive animals. PEAQX, the specific antagonist of NMDAR subunit 2A (GluN2A) was injected into both side of the PVN of two-kidney, one clip (2K1C) renal hypertensive rats and control (normotensive rats) for three weeks. Three weeks of PEAQX infusion significantly reduced the blood pressure of the 2K1C rats. It managed to resume the balance between excitatory and inhibitory neural transmitters, reduce the level of pro-inflammatory cytokines and reactive oxygen species in the PVN, and reduce the level of norepinephrine in plasma of the 2K1C rats. PEAQX administration also largely reduced the transcription and translation levels of GluN2A and changed the expression levels of NMDAR subunit 1 and 2B (GluN1 and GluN2B). In addition, NMDAR was known to function through activating the extracellular regulated protein kinases (ERK) or phosphatidylinositol 3-kinase/protein kinase B (PI3K/Akt) pathways. In our study we found that in the PVN of 2K1C rats treated with PEAQX, the phosphorylation levels of mitogen-activated protein kinase kinase (MEK), ERK1/2 and cAMP-response element binding protein (CREB) significantly reduced, while the phosphorylation level of PI3K didn't change significantly. Chronic blockade of GluN2A alleviates hypertension through suppression of MEK/ERK/CREB pathway.

Long-term depression of excitatory transmission in the lateral septum.

Neurons in the lateral septum (LS) integrate glutamatergic synaptic inputs, primarily from hippocampus, and send inhibitory projections to brain regions involved in reward and the generation of motivated behavior. Motivated learning and drugs of abuse have been shown to induce long-term changes in the strength of glutamatergic synapses in the LS, but the cellular mechanisms underlying long-term synaptic modification in the LS are poorly understood. Here, we examined synaptic transmission and long-term depression (LTD) in brain slices prepared from male and female C57BL/6 mice. No sex differences were observed in whole cell patch-clamp recordings of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor (AMPA-R)- and N-methyl-d-aspartate receptor (NMDA-R)-mediated currents. Low-frequency stimulation of the fimbria fiber bundle (1 Hz 15 min) induced LTD of the LS field excitatory postsynaptic potential (fEPSP). Induction of LTD was blocked by the NMDA-R antagonist (d)-2-amino-5-phosphonovaleric acid (APV), but not the selective antagonist of GluN2B-containing NMDA-Rs ifenprodil. These results demonstrate the NMDA-R dependence of LTD in the LS. The LS is a sexually dimorphic structure, and sex differences in glutamatergic transmission have been reported in vivo; our results suggest sex differences observed in vivo result from network activity rather than intrinsic differences in glutamatergic transmission.NEW & NOTEWORTHY The lateral septum (LS) integrates information from hippocampus and other regions to provide context-dependent (top down or higher order) regulation of mood and motivated behavior. Learning and drugs of abuse induce long-term changes in the strength of glutamatergic projections to the LS; however, the cellular mechanisms underlying such changes are poorly understood. Here, we demonstrate there are no apparent sex differences in fast excitatory transmission and that long-term synaptic depression in the LS is NMDA-R dependent.

Cholinergic Signaling, Neural Excitability, and Epilepsy.

Epilepsy is a common brain disorder characterized by recurrent epileptic seizures with neuronal hyperexcitability. Apart from the classical imbalance between excitatory glutamatergic transmission and inhibitory γ-aminobutyric acidergic transmission, cumulative evidence suggest that cholinergic signaling is crucially involved in the modulation of neural excitability and epilepsy. In this review, we briefly describe the distribution of cholinergic neurons, muscarinic, and nicotinic receptors in the central nervous system and their relationship with neural excitability. Then, we summarize the findings from experimental and clinical research on the role of cholinergic signaling in epilepsy. Furthermore, we provide some perspectives on future investigation to reveal the precise role of the cholinergic system in epilepsy.

Elucidation of the Role of Transient Receptor Potential Vanilloid-1 (TRPV1) Channels in Epileptogenesis

The transient receptor potential vanilloid-1 (TRPV1), previously known as the capsaicin receptor or vanilloid receptor 1 (VR1) is a nonselective cation channel that acts as an integrator of nociceptive information in sensory neurons and their sensory nerve endings with unmyelinated (C) or thin myelinated (Aδ) fibers. It is activated by capsaicin, resiniferatoxin, piperine, noxious heat (&gt; 43ºC), protons, lipoxygenase products, and some endogenous cannabinoids. TRPV1 receptors are also expressed in the brain on neurons, glia cells and pericytes and might be involved in the modulation of epileptogenesis. TRPV1 modulates synaptic plasticity and neurotransmission, mediates long-term depression of glutamate release in the hippocampus and suppress excitatory transmission in dentate gyrus. TRPV1-knockout mice have altered susceptibility to hyperthermic seizures. Studies in vitro showed that capsaicin reduced epileptiform activity but increased neuronal discharge in excitable cells. Capsaicin given via systemic routes at low doses was shown to reduce seizures induced by kainic acid and pentylenetetrazole and to afford neuroprotection of hippocampus in vivo. These effects were associated with reduced oxidative stress and inflammation in brain. In contrast, high doses of capsaicin either elicited or enhanced seizures in animals. In addition, piperine, a TRPV1 agonist, demonstrated anti-epileptic activity in several animal models via a multiplicity of mechanisms. Moreover, non-psychotropic cannabinoids such as cannabidiol and cannabidivarin, the endocannabinoid anandamide, and acetaminophen demonstrated anti-epileptiform activity in vivo and in vitro via mechanisms that might involve TRPV1 receptors. By surveying recent research findings, this review article is intended to present the current research status on the involvement of TRPV1 receptors in epileptogenesis so as to stimulate further investigations into the detailed molecular mechanisms by which capsaicin as well as other chemical modalities impact epileptogenesis via modulating TRPV1 channels. (First online: Apr 12, 2021)

Identification of an endogenous glutamatergic transmitter system controlling excitability and conductivity of atrial cardiomyocytes

As an excitatory transmitter system, the glutamatergic transmitter system controls excitability and conductivity of neurons. Since both cardiomyocytes and neurons are excitable cells, we hypothesized that cardiomyocytes may also be regulated by a similar system. Here, we have demonstrated that atrial cardiomyocytes have an intrinsic glutamatergic transmitter system, which regulates the generation and propagation of action potentials. First, there are abundant vesicles containing glutamate beneath the plasma membrane of rat atrial cardiomyocytes. Second, rat atrial cardiomyocytes express key elements of the glutamatergic transmitter system, such as the glutamate metabolic enzyme, ionotropic glutamate receptors (iGluRs), and glutamate transporters. Third, iGluR agonists evoke iGluR-gated currents and decrease the threshold of electrical excitability in rat atrial cardiomyocytes. Fourth, iGluR antagonists strikingly attenuate the conduction velocity of electrical impulses in rat atrial myocardium both in vitro and in vivo. Knockdown of GRIA3 or GRIN1, two highly expressed iGluR subtypes in atria, drastically decreased the excitatory firing rate and slowed down the electrical conduction velocity in cultured human induced pluripotent stem cell (iPSC)-derived atrial cardiomyocyte monolayers. Finally, iGluR antagonists effectively prevent and terminate atrial fibrillation in a rat isolated heart model. In addition, the key elements of the glutamatergic transmitter system are also present and show electrophysiological functions in human atrial cardiomyocytes. In conclusion, our data reveal an intrinsic glutamatergic transmitter system directly modulating excitability and conductivity of atrial cardiomyocytes through controlling iGluR-gated currents. Manipulation of this system may open potential new avenues for therapeutic intervention of cardiac arrhythmias.

Input-selective adenosine A1 receptor-mediated synaptic depression of excitatory transmission in dorsal striatum

The medial (DMS) and lateral (DLS) dorsal striatum differentially drive goal-directed and habitual/compulsive behaviors, respectively, and are implicated in a variety of neuropsychiatric disorders. These subregions receive distinct inputs from cortical and thalamic regions which uniquely determine dorsal striatal activity and function. Adenosine A1 receptors (A1Rs) are prolific within striatum and regulate excitatory glutamate transmission. Thus, A1Rs may have regionally-specific effects on neuroadaptive processes which may ultimately influence striatally-mediated behaviors. The occurrence of A1R-driven plasticity at specific excitatory inputs to dorsal striatum is currently unknown. To better understand how A1Rs may influence these behaviors, we first sought to understand how A1Rs modulate these distinct inputs. We evaluated A1R-mediated inhibition of cortico- and thalamostriatal transmission using in vitro whole-cell, patch clamp slice electrophysiology recordings in medium spiny neurons from both the DLS and DMS of C57BL/6J mice in conjunction with optogenetic approaches. In addition, conditional A1R KO mice lacking A1Rs at specific striatal inputs to DMS and DLS were generated to directly determine the role of these presynaptic A1Rs on the measured electrophysiological responses. Activation of presynaptic A1Rs produced significant and prolonged synaptic depression (A1R-SD) of excitatory transmission in the both the DLS and DMS of male and female animals. Our findings indicate that A1R-SD at corticostriatal and thalamostriatal inputs to DLS can be additive and that A1R-SD in DMS occurs primarily at thalamostriatal inputs. These findings advance the field’s understanding of the functional roles of A1Rs in striatum and implicate their potential contribution to neuropsychiatric diseases.

Glutamatergic plasticity within neurocircuits of the dorsal vagal complex and the regulation of gastric functions.

The meticulous regulation of the gastrointestinal (GI) tract is required for the coordination of gastric motility and emptying, intestinal secretion, absorption, and transit as well as for the overarching management of food intake and energy homeostasis. Disruption of GI functions is associated with the development of severe GI disorders and the alteration of food intake and caloric balance. Functional GI disorders as well as the dysregulation of energy balance and food intake are frequently associated with, or result from, alterations in the central regulation of GI control. The faithful and rapid transmission of information from the stomach and upper GI tract to second-order neurons of the nucleus of the tractus solitarius (NTS) relies on the delicate modulation of excitatory glutamatergic transmission, as does the relay of integrated signals from the NTS to parasympathetic efferent neurons of the dorsal motor nucleus of the vagus (DMV). Many studies have focused on understanding the physiological and pathophysiological modulation of these glutamatergic synapses, although their role in the control and regulation of GI functions has lagged behind that of cardiovascular and respiratory functions. The purpose of this review is to examine the current literature exploring the role of glutamatergic transmission in the DVC in the regulation of GI functions.