Retrograde GABA signaling adjusts sound localization by balancing excitation and inhibition in the brainstem

Central processing of acoustic cues is critically dependent on the balance between excitation and inhibition. This balance is particularly important for auditory neurons in the lateral superior olive, because these compare excitatory inputs from one ear and inhibitory inputs from the other ear to compute sound source location. By applying GABA(B) receptor antagonists during sound stimulation in vivo, it was revealed that these neurons adjust their binaural sensitivity through GABA(B) receptors. Using an in vitro approach, we then demonstrate that these neurons release GABA during spiking activity. Consequently, GABA differentially regulates transmitter release from the excitatory and inhibitory terminals via feedback to presynaptic GABA(B) receptors. Modulation of the synaptic input strength, by putative retrograde release of neurotransmitter, may enable these auditory neurons to rapidly adjust the balance between excitation and inhibition, and thus their binaural sensitivity, which could play an important role as an adaptation to various listening situations.     

Evidence Disputing the Link Between Seizure Activity and High Extracellular Glutamate

Abstract: As seizures in experimental models can be induced by the activation and suppressed by the inhibition of glutamate receptors, it is often proposed that a high extracellular glutamate level subsequent to excessive presynaptic release and/or altered glutamate uptake is epileptogenic. The purpose of this study was to ascertain the link between seizure activity and high extracellular glutamate. To assist the detection of any putative rise in extracellular glutamate during seizures, microdialysis was coupled to enzyme-amperometric detection of glutamate, which provides maximal sensitivity and time resolution. Electrical activity and field potential were also recorded through the dialysis membrane to confirm that epileptic activity was present at the sampling site. No increase in dialysate glutamate content was detected during picrotoxin-induced seizures, even when the K⁺ concentration in the perfusion medium was raised to 50% above that measured previously during paroxysmal activity. In addition, sustained inhibition of glutamate uptake by l - trans -pyrrolidine-2,4-dicarboxylate increased the extracellular glutamate level >20-fold but did not produce electrophysiological changes indicative of excessive excitation. These findings indicate that seizures are not necessarily accompanied by an increased extracellular glutamate level and that increased glutamatergic excitation in epilepsy may result from other abnormalities such as increased density of glutamate receptors, enhanced activation subsequent to reduced modulation, or sprouting of glutamatergic synapses.     

Up-regulation of neuropeptide Y levels and modulation of glutamate release through neuropeptide Y receptors in the hippocampus of kainate-induced epileptic rats

Kainate-induced epilepsy has been shown to be associated with increased levels of neuropeptide Y (NPY) in the rat hippocampus. However, there is no information on how increased levels of this peptide might modulate excitation in kainate-induced epilepsy. In this work, we investigated the modulation of glutamate release by NPY receptors in hippocampal synaptosomes isolated from epileptic rats. In the acute phase of epilepsy, a transient decrease in the efficiency of NPY and selective NPY receptor agonists in inhibiting glutamate release was observed. Moreover, in the chronic epileptic hippocampus, a decrease in the efficiency of NPY and the Y(2) receptor agonist, NPY13-36, was also found. Simultaneously, we observed that the epileptic hippocampus expresses higher levels of NPY, which may account for an increased basal inhibition of glutamate release. Consistently, the blockade of Y(2) receptors increased KCl-evoked glutamate release, and there was an increase in Y(2) receptor mRNA levels 30 days after kainic acid injection, suggesting a basal effect of NPY through Y(2) receptors. Taken together, these results indicate that an increased function of the NPY modulatory system in the epileptic hippocampus may contribute to basal inhibition of glutamate release and control hyperexcitability.     

Role of astrocytes in the maintenance and modulation of glutamatergic and GABAergic neurotransmission

The functional activity in the brain is primarily composed of an interplay between excitation and inhibition. In any given region the output is based upon a complex processing of incoming signals that require both excitatory and inhibitory units. Moreover, these units must be regulated and balanced such that an integrated and finely tuned response is generated. In each of these units or synapses the activity depends on biosynthesis, release, receptor interaction, and inactivation of the neurotransmitter in question; thus, it is easily understood that each of these processes needs to be highly regulated and controlled. It is interesting to note that in case of the most prevailing neurotransmitters, glutamate and GABA, which mediate excitation and inhibition, respectively, the inactivation process is primarily maintained by highly efficient, high-affinity transport systems capable of maintaining transmembrane concentration gradients of these amino acids of 10⁴–10⁵-fold. The demonstration of the presence of transporters for glutamate and GABA in both neuronal and astrocytic elements naturally raises the question of the functional importance of the astrocytes in the regulation of the level of the neurotransmitters in the synaptic cleft and hence for the activity of excitatory and inhibitory neurotransmission. Obviously, this discussion has important implications for the understanding of the role of astrocytes in disease states in which imbalances between excitation and inhibition are a triggering factor, for example, epilepsy and neurodegeneration.     

Roles of Na(+)-Ca2+ exchange and of mitochondria in the regulation of presynaptic Ca2+ and spontaneous glutamate release

The release of neurotransmitter from presynaptic terminals depends on an increase in the intracellular Ca2+ concentration ([Ca2+]i). In addition to the opening of presynaptic Ca2+ channels during excitation, other Ca2+ transport systems may be involved in changes in [Ca2+]i. We have studied the regulation of [Ca2+]i in nerve terminals of hippocampal cells in culture by the Na(+)-Ca2+ exchanger and by mitochondria. In addition, we have measured changes in the frequency of spontaneous excitatory postsynaptic currents (sEPSC) before and after the inhibition of the exchanger and of mitochondrial metabolism. We found rather heterogeneous [Ca2+]i responses of individual presynaptic terminals after inhibition of Na(+)-Ca2+ exchange. The increase in [Ca2+]i became more uniform and much larger after additional treatment of the cells with mitochondrial inhibitors. Correspondingly, sEPSC frequencies changed very little when only Na(+)-Ca2+ exchange was inhibited, but increased dramatically after additional inhibition of mitochondria. Our results provide evidence for prominent roles of Na(+)-Ca2+ exchange and mitochondria in presynaptic Ca2+ regulation and spontaneous glutamate release.     

Presynaptic GABAB Receptor Modulation of Glutamate Exocytosis from Rat Cerebrocortical Nerve Terminals: Receptor Decoupling by Protein Kinase C

Abstract: GABA and the GABA_B receptor agonist (−)-baclofen inhibited 4-aminopyridine (4AP)- and KCl-evoked, Ca²⁺-dependent glutamate release from rat cerebrocortical synaptosomes. The GABA_B receptor antagonist CGP 35348, prevented this inhibition of glutamate release, but phaclofen had no effect. (−)-Baclofen-mediated inhibition of glutamate release was insensitive to 2 µg/ml pertussis toxin. As determined by examining the mechanism of GABA_B receptor modulation of glutamate release, (−)-baclofen caused a significant reduction in 4AP-evoked Ca²⁺ influx into synaptosomes. The agonist did not alter the resting synaptosomal membrane potential or 4AP-mediated depolarization; thus, the inhibition of Ca²⁺ influx could not be attributed to GABA_B receptor activation causing a decrease in synaptosomal excitability. Ionomycin-mediated glutamate release was not affected by (−)-baclofen, indicating that GABA_B receptors in this preparation are not coupled directly to the exocytotic machinery. Instead, the data invoke a direct coupling of GABA_B receptors to voltage-dependent Ca²⁺ channels linked to glutamate release. This coupling was subject to regulation by protein kinase C (PKC), because (−)-baclofen-mediated inhibition of 4AP-evoked glutamate release was reversed when PKC was stimulated with phorbol ester. This may therefore represent a mechanism by which inhibitory and facilitatory presynaptic receptor inputs interplay to fine-tune transmitter release.     

The anxiety-like phenotype of 5-HT receptor null mice is associated with genetic background-specific perturbations in the prefrontal cortex GABA-glutamate system

A deficit in the serotonin 5-HT(1A) receptor has been found in panic and post-traumatic stress disorders, and genetic inactivation of the receptor results in an anxiety-like phenotype in mice on both the C57Bl6 and Swiss-Webster genetic backgrounds. Anxiety is associated with increased neuronal activity in the prefrontal cortex and here we describe changes in glutamate and GABA uptake of C57Bl6 receptor null mice. Although these alterations were not present in Swiss-Webster null mice, we have previously reported reductions in GABA(A) receptor expression in these but not in C57Bl6 null mice. This demonstrates that inactivation of the 5-HT(1A) receptor elicits different and genetic background-dependent perturbations in the prefrontal cortex GABA/glutamate system. These perturbations can result in a change in the balance between excitation and inhibition, and indeed both C57Bl6 and Swiss-Webster null mice show signs of increased neuronal excitability. Because neuronal activity in the prefrontal cortex controls the extent of response to anxiogenic stimuli, the genetic background-specific perturbations in glutamate and GABA neurotransmission in C57Bl6 and Swiss-Webster 5-HT(1A) receptor null mice may contribute to their shared anxiety phenotype. Our study shows that multiple strains of genetically altered mice could help us to understand the common and individual features of anxiety.     

Protein phosphatase 1 and 2A inhibitors prolong the switch in the control of glutamate release by group I metabotropic glutamate receptors: characterization of the inhibitory pathway

We have addressed the role of protein phosphatases (PPs) in the modulation of the switch in glutamate release observed after repetitive stimulation of group I metabotropic glutamate receptors (mGluRs). In cerebrocortical nerve terminals the agonist (S:)-3, 5-dihydroxyphenylglycine facilitated evoked glutamate release. However, a second stimulation, 5 min later, reduced rather than facilitated this release. This switch in the control of glutamate release was reversed when a 30-min interval was left between stimulations. Inhibition of the endogenous PPs, PP1 and PP2A, with calyculin A and okadaic acid prevented the recovery of the facilitatory response and maintained the receptor permanently coupled to the inhibitory pathway. The inhibitors of PP2B, cyclosporin A and cypermethrine, had no effect. The inhibition of glutamate release was insensitive to pertussis toxin and was the result of the loss of the release component coupled to N-type Ca(2+) channels. This inhibitory action was suppressed by addition of the protein kinase C activator 4beta-phorbol 12,13-dibutyrate. We conclude that the balance between protein kinase and phosphatase activity at the nerve terminal plays a key role in accommodating the modulation of glutamate release by group I mGluRs.     

Presynaptic serotonergic modulation of spontaneous and miniature synaptic activity in frog lumbar motoneurons

The effects of serotonin (5-HT, 30 μM) on spontaneous and miniature synaptic activity in lumbar motoneurons from the isolated Rana ridibunda spinal cord were investigated using intracellular recording. 5-HT increased the frequency of spontaneous (sPSPs) and miniature postsynaptic potentials (mPSPs). The effect of 5-HT on different subpopulations of mPSPs was multidirectional: it increased the frequency of glutamatergic excitatory mPSPs by 18% and decreased the frequency of glycinergic inhibitory mPSPs by 28%, but had no effect on the frequency of GABAergic inhibitory mPSPs. The amplitude and kinetic parameters of any subpopulation of mPSPs did not change. The data obtained show that 5-HT regulates the probability of glutamate and glycine release from the presynaptic terminals ending at frog spinal motoneurons. 5-HT shifts the balance between synaptic excitation and inhibition in the spinal neural network toward excitation. Thus, 5-HT participates in control of motor output and provides its facilitation.     

Dale's principle and glutamate corelease from ventral midbrain dopamine neurons

Summary. While direct application of dopamine modulates postsynaptic activity, electrical stimulation of dopamine neurons typically evokes excitation. Most of this excitation appears to be due to activation of collateral pathways; however, several lines of evidence have suggested that there is a monosynaptic component due to glutamate corelease by dopamine neurons. Recently, more direct evidence obtained in culture has shown that ventral midbrain dopamine neurons release both dopamine and glutamate. Moreover, they appear to do so from separate release sites, calling into question recent modifications of Dale's Principle. The neurochemical phenotype of a given synapse may be determined by subcellular neurotransmitter levels, uptake, or storage. However, the relationship between dopamine and glutamate release from dopamine neuron synapses in the intact brain – and the mechanisms involved – has yet to be resolved. Received August 31, 1999 Accepted September 20, 1999     

Glutamate/glutamine metabolism coupling between astrocytes and glioma cells: Neuroprotection and inhibition of glioma growth

Glioma glutamate release has been shown to promote the growth of glioma cells and induce neuronal injuries from epilepsy to neuronal death. However, potential counteractions from normal astrocytes against glioma glutamate release have not been fully evaluated. In this study, we investigated the glutamate/glutamine cycling between glioma cells and astrocytes and their impact on neuronal function. Co-cultures of glioma cells with astrocytes (CGA) in direct contact were established under different mix ratio of astrocyte/glioma. Culture medium conditioned in these CGAs were sampled for HPLC measurement, for neuronal ratiometric calcium imaging, and for neuronal survival assay. We found: (1) High levels of glutaminase expression in glioma cells, but not in astrocytes, glutaminase enables glioma cells to release large amount of glutamate in the presence of glutamine. (2) Glutamate levels in CGAs were directly determined by the astrocyte/glioma ratios, indicating a balance between glioma glutamate release and astrocyte glutamate uptake. (3) Culture media from CGAs of higher glioma/astrocyte ratios induced stronger neuronal Ca²⁺ response and more severe neuronal death. (4) Co-culturing with astrocytes significantly reduced the growth rate of glioma cells. These results indicate that normal astrocytes in the brain play pivotal roles in glioma growth inhibition and in reducing neuronal injuries from glioma glutamate release. However, as tumor growth, the protective role of astrocytes gradually succumb to glioma cells.     

Glial cell-derived glutamate mediates autocrine cell volume regulation in the retina: activation by VEGF

Astroglial cells are a source for gliotransmitters such as glutamate and ATP. We demonstrate here that gliotransmitters have autocrine functions in the regulation of cellular volume. Hypoosmotic stress in the presence of inflammatory mediators or oxidative stress, and during blockade or down-regulation of potassium channels, induces swelling of retinal glial cells. Vascular endothelial growth factor inhibits the osmotic swelling of glial cells in retinal slices or isolated cells. This effect was mediated by a kinase domain region/flk-1 receptor-evoked calcium dependent release of glutamate from glial cells, and subsequent stimulation of glial group I/II metabotropic glutamate receptors. Activation of kinase domain region/flk-1 or glutamate receptors evoked an autocrine swelling-inhibitory purinergic signaling cascade that was calcium-independent. This cascade involved the release of ATP and adenosine, and the activation of purinergic P2Y₁ and adenosine A1 receptors, resulting in the opening of potassium and chloride channels and inhibition of cellular swelling. The glutamatergic-purinergic regulation of the glial cell volume may be functionally important in the homeostasis of the extracellular space volume during intense neuronal activation which is associated with a swelling of neuronal cell structures in the retina. However, glial cell-derived glutamate may also contribute to the swelling of activated neurons since metabolic poisoning of glial cells by iodoacetate inhibits the neuronal cell swelling mediated by activation of ionotropic glutamate receptors.     

Synaptic Neurotransmitter-Gated Receptors

Since the discovery of the major excitatory and inhibitory neurotransmitters and their receptors in the brain, many have deliberated over their likely structures and how these may relate to function. This was initially satisfied by the determination of the first amino acid sequences of the Cys-loop receptors that recognized acetylcholine, serotonin, GABA, and glycine, followed later by similar determinations for the glutamate receptors, comprising non-NMDA and NMDA subtypes. The last decade has seen a rapid advance resulting in the first structures of Cys-loop receptors, related bacterial and molluscan homologs, and glutamate receptors, determined down to atomic resolution. This now provides a basis for determining not just the complete structures of these important receptor classes, but also for understanding how various domains and residues interact during agonist binding, receptor activation, and channel opening, including allosteric modulation. This article reviews our current understanding of these mechanisms for the Cys-loop and glutamate receptor families.To understand how neurons communicate with each other requires a fundamental understanding of neurotransmitter receptor structure and function. Neurotransmitter-gated ion channels, also known as ionotropic receptors, are responsible for fast synaptic transmission. They decode chemical signals into electrical responses, thereby transmitting information from one neuron to another. Their suitability for this important task relies on their ability to respond very rapidly to the transient release of neurotransmitter to affect cell excitability.In the central nervous system (CNS), fast synaptic transmission results in two main effects: neuronal excitation and inhibition. For excitation, the principal neurotransmitter involved is glutamate, which interacts with ionotropic (integral ion channel) and metabotropic (second-messenger signaling) receptors. The ionotropic glutamate receptors are permeable to cations, which directly cause excitation. Acetylcholine and serotonin can also activate specific cation-selective ionotropic receptors to affect neuronal excitation. For controlling cell excitability, inhibition is important, and this is mediated by the neurotransmitters GABA and glycine, causing an increased flux of anions. GABA predominates as the major inhibitory transmitter throughout the CNS, whereas glycine is of greater importance in the spinal cord and brainstem. They both activate specific receptors—for GABA, there are ionotropic and metabotropic receptors, whereas for glycine, only ionotropic receptors are known to date.Together with acetylcholine- and serotonin-gated channels, GABA and glycine ionotropic receptors form the superfamily of Cys-loop receptors, which differs in many aspects from the superfamily of ionotropic glutamate receptors. Over the last two decades, our knowledge of the structure and function of ionotropic receptors has grown rapidly. In this article, we summarize our current understanding of the molecular operation of these receptors and how we can now begin to interpret the role of receptor structure in agonist binding, channel activation, and allosteric modulation of Cys-loop and glutamate receptor families. Further details on the regulation and trafficking of neurotransmitter receptors in synaptic structure and plasticity can be found in accompanying articles.     

Inhibition of Ca2+-dependent glutamate release from cerebral cortex synaptosomes of rats with experimental autoimmune encephalomyelitis

Several pathological studies have revealed a prominent involvement of the cerebral cortex in patients with multiple sclerosis (MS). In order to better understand the events that lead to the progressive neuronal dysfunction in MS, herein we explore the contribution of the glutamatergic release in cerebral cortex synaptosomes isolated from rats with experimental autoimmune encephalomyelitis, an animal model reproducing many features of MS. We found that the Ca²⁺-dependent but not the Ca²⁺-independent glutamate release induced by KCl and 4-aminopyridine was significantly decreased during the acute stage of the disease. This inhibited release coincides with the onset of the clinical signs and after 24 h tends to recover the level of the control animals. The results also showed an inhibition of the glutamate release stimulated by ionomycin. When the animals were totally recovered from clinical signs, the neurotransmitter release stimulated by the different inductors was similar to the controls. Examination of the cytosolic Ca²⁺ using fura-2-acetoxymethyl ester revealed that the inhibition of glutamate release could not be attributed to a reduction in voltage-dependent Ca²⁺ influx. However, this inhibition was concomitant with a lower phosphorylation of synapsin I at P-site1. Our results show that the inhibition observed on the Ca²⁺-dependent neurotransmitter release from cerebral cortex synaptosomes in experimental autoimmune encephalomyelitis is specific and correlates with the beginning of the clinical disease. Moreover, they suggest an alteration in the metabolism of proteins involved in the vesicular glutamate release more than a deregulation in the influx of cytosolic Ca²⁺.     

Effect of Low pH on Glutamate Uptake and Release in Isolated Presynaptic Endings from Rat Brain

The effect of acidification of the incubation medium on the membrane potential and glutamate uptake and release was studied in isolated presynaptic neuronal endings (synaptosomes) from rat brain. Using the fluorescent probe diS-C₃-(5), a rapid depolarization of plasma membrane was detected at pH 6.0, most probably as a result of the inhibition of the sodium pump and potassium channel blockade. The membrane potential decrease did not result in increase of basal efflux of glutamate. Glutamate release following K⁺-induced depolarization was decreased upon lowering pH to 6.0. Acidosis inhibited mainly calcium-dependent (vesicular) release of glutamate and did not significantly reduce [¹⁴C]glutamate uptake. This inhibition of glutamate release but not of glutamate uptake may be a mechanism of the protective effect of acidosis during brain ischemia.     

Metabolic control of vesicular glutamate transport and release

Fasting has been used to control epilepsy since antiquity, but the mechanism of coupling between metabolic state and excitatory neurotransmission remains unknown. Previous work has shown that the vesicular glutamate transporters (VGLUTs) required for exocytotic release of glutamate undergo an unusual form of regulation by Cl(-). Using functional reconstitution of the purified VGLUTs into proteoliposomes, we now show that Cl(-) acts as an allosteric activator, and the ketone bodies that increase with fasting inhibit glutamate release by competing with Cl(-) at the site of allosteric regulation. Consistent with these observations, acetoacetate reduced quantal size at hippocampal synapses and suppresses glutamate release and seizures evoked with 4-aminopyridine in the brain. The results indicate an unsuspected link between metabolic state and excitatory neurotransmission through anion-dependent regulation of VGLUT activity.     

Differential regulation of spontaneous and evoked neurotransmitter release at central synapses

Recent studies have begun to scrutinize the presynaptic machinery and vesicle populations that give rise to action potential evoked and spontaneous forms of neurotransmitter release. In several cases this work produced unexpected results which lend support to the notion that regulation, mechanisms, postsynaptic targets and possibly presynaptic origins of evoked and spontaneous neurotransmitter release differ. Furthermore, the list of regulatory pathways that impact spontaneous and evoked release in a divergent manner is rapidly growing. These findings challenge our classical views on the relationship between evoked and spontaneous neurotransmission. In contrast to the well-characterized neuromodulatory pathways that equally suppress or augment all forms of neurotransmitter release, molecular substrates specifically controlling spontaneous release remain unclear. In this review, we outline possible mechanisms that may underlie the differential regulation of distinct forms of neurotransmission and help demultiplex complex neuronal signals and generate parallel signaling events at their postsynaptic targets.     

Presynaptic kainate receptors that enhance the release of GABA on CA1 hippocampal interneurons

We report that kainate receptors are present on presynaptic GABAergic terminals contacting interneurons and that their activation increases GABA release. Application of kainate increased the frequency of miniature inhibitory postsynaptic currents recorded in CA1 interneurons. Local applications of glutamate but not of AMPA or NMDA also increased GABA quantal release. Application of kainate as well as synaptically released glutamate reduced the number of failures of GABAergic neurotransmission between interneurons. Thus, activation of presynaptic kainate receptors increases the probability of GABA release at interneuron-interneuron synapses. Glutamate may selectively control the communication between interneurons by increasing their mutual inhibition.     

Defining the role of astrocytes in neuromodulation

Astrocytes undergo elevations in intracellular calcium following activation of metabotropic receptors, which may trigger glutamate secretion and excitation of surrounding neurons. In this issue of Neuron, Fiacco et al. use transgenic mice that express a foreign G(q)-coupled receptor in astrocytes to show that selective stimulation of astrocytes is not sufficient to induce the release of glutamate.     

Estradiol induces formation of dendritic spines in hippocampal neurons: functional correlates

Dissociated cultured rat hippocampal pyramidal neurons respond to estradiol with a time-dependent, twofold increase in density of their dendritic spines. This effect is mediated by an estrogen receptor, probably of the alpha nuclear receptor type. In searching for the molecular mechanisms leading from the initial activation of the estrogen receptor to the final formation of new dendritic spines, we found that estradiol acts on GABAergic interneurons expressing the estrogen receptor by decreasing their inhibitory tone. In culture, this is assumed to cause a shift in the balance between excitation and inhibition toward enhanced excitation, overactivation of the pyramidal neurons, and subsequent formation of novel dendritic spines. The action of estradiol on spine formation is mediated by phosphorylation of cyclic AMP response element binding protein in the pyramidal neurons and is blocked when inhibition is enhanced by diazepam and when excitation is blocked by tetrodotoxin. Progesterone blocks the effect of estradiol on dendritic spines through its conversion to tetrahydroprogesterone, which enhances GABAergic inhibition. Subsequent to formation of novel dendritic spines, there is an increase in the density of glutamatergic receptors in the affected cells, an increase in the cellular calcium response to glutamate, and an increase in network synaptic activity among the cultured neurons.