Enhanced Function and Overexpression of Metabotropic Glutamate Receptors 1 and 5 in the Spinal Cord of the SOD1G93A Mouse Model of Amyotrophic Lateral Sclerosis during Disease Progression.

Glutamate (Glu)-mediated excitotoxicity is a major cause of amyotrophic lateral sclerosis (ALS) and our previous work highlighted that abnormal Glu release may represent a leading mechanism for excessive synaptic Glu. We demonstrated that group I metabotropic Glu receptors (mGluR1, mGluR5) produced abnormal Glu release in SOD1G93A mouse spinal cord at a late disease stage (120 days). Here, we studied this phenomenon in pre-symptomatic (30 and 60 days) and early-symptomatic (90 days) SOD1G93A mice. The mGluR1/5 agonist (S)-3,5-Dihydroxyphenylglycine (3,5-DHPG) concentration dependently stimulated the release of [3H]d-Aspartate ([3H]d-Asp), which was comparable in 30- and 60-day-old wild type mice and SOD1G93A mice. At variance, [3H]d-Asp release was significantly augmented in 90-day-old SOD1G93A mice and both mGluR1 and mGluR5 were involved. The 3,5-DHPG-induced [3H]d-Asp release was exocytotic, being of vesicular origin and mediated by intra-terminal Ca2+ release. mGluR1 and mGluR5 expression was increased in Glu spinal cord axon terminals of 90-day-old SOD1G93A mice, but not in the whole axon terminal population. Interestingly, mGluR1 and mGluR5 were significantly augmented in total spinal cord tissue already at 60 days. Thus, function and expression of group I mGluRs are enhanced in the early-symptomatic SOD1G93A mouse spinal cord, possibly participating in excessive Glu transmission and supporting their implication in ALS. Please define all abbreviations the first time they appear in the abstract, the main text, and the first figure or table caption.

A new function for glycine GlyT2 transporters: Stimulation of γ-aminobutyric acid release from cerebellar nerve terminals through GAT1 transporter reversal and Ca(2+)-dependent anion channels.

Glycine GlyT2 transporters are localized on glycine-storing nerve endings. Their main function is to accumulate glycine to replenish synaptic vesicles. Glycine was reported to be costored with γ-aminobutyric acid (GABA) in cerebellar interneurons that may coexpress glycine and GABA transporters, and this is confirmed here by confocal microscopy analysis showing coexpression of GAT1 and GlyT2 transporters on microtubule-associated protein-2-positive synaptosomes. It was found that GABA uptake elicited glycine release from cerebellar nerve endings by various mechanisms. We investigated whether and by what mechanisms activation of glycine transporters could mediate release of GABA. Nerve endings purified from cerebellum were prelabeled with [3H]GABA and exposed to glycine. Glycine stimulated [3H]GABA release in a concentration-dependent manner. The glycine effect was insensitive to strychnine or to 5,7-dichlorokynurenate but it was abolished when GlyT2 transporters were blocked. About 20% of the evoked release was dependent on external Ca2+ entered by reversal of plasmalemmal Na+/Ca2+ exchangers. A significant portion of the GlyT2-mediated release of [3H]GABA (about 50% of the external Ca(2+)-independent release) occurred by reversal of GABA GAT1 transporters. Na+ ions, reaching the cytosol during glycine uptake through GlyT2, activated mitochondrial Na+/Ca2+ exchangers, causing an increase in cytosolic Ca2+, which in turn triggered a Ca(2+)-induced Ca2+ release process at inositoltrisphosphate receptors. Finally, the increased availability of Ca2+ in the cytosol allowed the opening of anion channels permeable to GABA. In conclusion, GlyT2 transporters not only take up glycine to replenish synaptic vesicles but can also mediate release of GABA by reversal of GAT1 and permeation through anion channels.

Interactions Involving Glycine and Other Amino Acid Neurotransmitters: Focus on Transporter-Mediated Regulation of Release and Glycine-Glutamate Crosstalk.

Glycine plays a pivotal role in the Central Nervous System (CNS), being a major inhibitory neurotransmitter as well as a co-agonist of Glutamate at excitatory NMDA receptors. Interactions involving Glycine and other neurotransmitters are the subject of different studies. Functional interactions among neurotransmitters include the modulation of release through release-regulating receptors but also through transporter-mediated mechanisms. Many transporter-mediated interactions involve the amino acid transmitters Glycine, Glutamate, and GABA. Different studies published during the last two decades investigated a number of transporter-mediated interactions in depth involving amino acid transmitters at the nerve terminal level in different CNS areas, providing details of mechanisms involved and suggesting pathophysiological significances. Here, this evidence is reviewed also considering additional recent information available in the literature, with a special (but not exclusive) focus on glycinergic neurotransmission and Glycine-Glutamate interactions. Some possible pharmacological implications, although partly speculative, are also discussed. Dysregulations in glycinergic and glutamatergic transmission are involved in relevant CNS pathologies. Pharmacological interventions on glycinergic targets (including receptors and transporters) are under study to develop novel therapies against serious CNS pathological states including pain, schizophrenia, epilepsy, and neurodegenerative diseases. Although with limitations, it is hoped to possibly contribute to a better understanding of the complex interactions between glycine-mediated neurotransmission and other major amino acid transmitters, also in view of the current interest in potential drugs acting on "glycinergic" targets.

Interactions between Glycine and Glutamate through Activation of Their Transporters in Hippocampal Nerve Terminals.

Evidence supports the pathophysiological relevance of crosstalk between the neurotransmitters Glycine and Glutamate and their close interactions; some reports even support the possibility of Glycine-Glutamate cotransmission in central nervous system (CNS) areas, including the hippocampus. Functional studies with isolated nerve terminals (synaptosomes) permit us to study transporter-mediated interactions between neurotransmitters that lead to the regulation of transmitter release. Our main aims here were: (i) to investigate release-regulating, transporter-mediated interactions between Glycine and Glutamate in hippocampal nerve terminals and (ii) to determine the coexistence of transporters for Glycine and Glutamate in these terminals. Purified synaptosomes, analyzed at the ultrastructural level via electron microscopy, were used as the experimental model. Mouse hippocampal synaptosomes were prelabeled with [3H]D-Aspartate or [3H]Glycine; the release of radiolabeled tracers was monitored with the superfusion technique. The main findings were that (i) exogenous Glycine stimulated [3H]D-Aspartate release, partly by activation of GlyT1 and in part, unusually, through GlyT2 transporters and that (ii) D-Aspartate stimulated [3H]glycine release by a process that was sensitive to Glutamate transporter blockers. Based on the features of the experimental model used, it is suggested that functional transporters for Glutamate and Glycine coexist in a small subset of hippocampal nerve terminals, a condition that may also be compatible with cotransmission; glycinergic and glutamatergic transporters exhibit different functions and mediate interactions between the neurotransmitters. It is hoped that increased information on Glutamate-Glycine interactions in different areas, including the hippocampus, will contribute to a better knowledge of drugs acting at "glycinergic" targets, currently under study in relation with different CNS pathologies.

Glycine release provoked by disturbed Na⁺, Na⁺ and Ca²âº homeostasis in cerebellar nerve endings: roles of Ca²âº channels, Na⁺/Ca²âº exchangers and GlyT2 transporter reversal.

Glycine release provoked by ion dysregulations typical of some neuropathological conditions was analyzed in cerebellar synaptosomes selectively pre-labelled with [³H]glycine through GlyT2 transporters and exposed in superfusion to KCl, 4-aminopyridine (4-AP) or veratridine. The overflows caused by relatively low concentrations of the releasers were largely external Ca²âº-dependent. Higher concentrations of KCl (50 mM) or veratridine (10 µM), but not of 4-AP (1 mM), involved also external Ca²âº-independent mechanisms. GlyT1-mediated release could not be observed; only the external Ca²âº-independent veratridine-evoked overflow occurred significantly by GlyT2 reversal. None of the three depolarizing agents activated store-operated or transient receptor potential or L-type Ca²âº channels. The overflows caused by KCl or 4-AP occurred in part by N- and P/Q-type voltage-sensitive calcium channel-dependent exocytosis. Significant portions of the external Ca²âº-dependent overflow evoked by KCl or 4-AP (and all that caused by veratridine) were mediated by reverse plasmalemmal Na⁺/Ca²âº exchangers. Significant contribution to the overflows evoked by KCl or veratridine came from Ca²âº originated through mitochondrial Na⁺/Ca²âº exchangers. Ca²âº-induced Ca²âº release (CICR) mediated by inositoltrisphosphate receptors (InsP3Rs) represents the final trigger of the glycine release evoked by high KCl. The overflows evoked by 4-AP or, less so, by veratridine also involved InsP3R-mediated CICR and, in part, CICR mediated by ryanodine receptors. To conclude, ionic dysregulations typical of ischemia and epilepsy caused glycine release in cerebellum by multiple differential mechanisms that may represent potential therapeutic targets.

Functional 'glial' GLYT1 glycine transporters expressed in neurons.

Glycine transporter 1 (GLYT1) and GLYT2 are the glycine transporters in CNS. While GLYT2 is largely expressed in glycinergic neurons, GLYT1 has long been considered to be exclusively present in glial cells. There is increasing evidence that significant amounts of the 'glial' transporter also exist on neurons, particularly on pre-synaptic nerve endings of glutamatergic neurons. The functions of 'neuronal GLYT1' may be manifold and are discussed in this review. Of major interest are the interactions between neuronal GLYT1 and glutamatergic receptors of the NMDA type the activity of which is modulated not only by astrocytic GLYT1 but also by neuronal GLYT1. Pathophysiological roles and therapeutic implications of neuronal GLYT1 are emerging from recent studies with genetically modified mice, particularly with animals lacking forebrain neuron-specific GLYT1 transporters. These mutant mice exhibit promnesic phenotypes reflecting enhancement of NMDA receptor function, as it occurs following administration of GLYT1 inhibitors. Inactivation of neuronal GLYT1 in the forebrain may represent an effective therapeutic intervention for the treatment of schizophrenia.

Ionic dysregulations typical of ischemia provoke release of glycine and GABA by multiple mechanisms.

Energy deprivation during ischemia causes dysregulations of ions, particularly sodium, potassium and calcium. Under these conditions, release of neurotransmitters is often enhanced and can occur by multiple mechanisms. The aim of this work was to characterize the modes of exit of glycine and GABA from nerve endings exposed to stimuli known to reproduce some of the ionic changes typical of ischemic conditions. Their approach was chosen instead of application of ischemic conditions because the release evoked during ischemia is mechanistically too heterogeneous. Mouse hippocampus and spinal cord synaptosomes, pre-labeled with [(3)H]glycine or [(3)H]GABA, were exposed in superfusion to 50 mM KCl or to 10 microM veratridine. The evoked overflows differed greatly between the two transmitters and between the two regions examined. Significant portions of the K(+)- and the veratridine-evoked overflows occurred by classical exocytosis. Carrier-mediated release of GABA, but not of glycine, was evoked by high K(+); GABA and, less so, glycine were released through transporter reversal by veratridine. External calcium-dependent overflows were only in part sensitive to omega-conotoxins; significant portions occurred following reversal of the plasmalemmal Na(+)/Ca(2+) exchanger. Finally, a relevant contribution to the overall transmitter overflows came from cytosolic calcium originating through the mitochondrial Na(+)/Ca(2+) exchanger. To conclude, ionic dysregulations typical of ischemia cause neurotransmitter release by heterogeneous mechanisms that differ depending on the transmitters and the CNS regions examined.

The GABA B receptor antagonists CGP35348 and CGP52432 inhibit glycine exocytosis: study with GABA B1- and GABA B2-deficient mice.

GABA(B) receptors mediate inhibition of neurotransmitter exocytosis from nerve endings. Unexpectedly, the well known GABA(B) receptor antagonist CGP35348 and, in part, the compound CGP52432, are now found to inhibit on their own the K(+)-evoked exocytosis of glycine when added at low micromolar concentrations to superfused mouse glycinergic nerve endings prelabelled with [(3)H]glycine through GLYT2 transporters. CGP35348 inhibited [(3)H]glycine release both in spinal cord and in hippocampus, but was also able to prevent the inhibitory effect of (-)-baclofen; CGP52432 exhibited intrinsic activity only in the hippocampus; in spinal cord, it behaved exclusively as a silent orthosteric antagonist by blocking the release inhibition brought about by (-)-baclofen. The intrinsic activity of CGP35348 in spinal cord was not prevented by CGP52432, indicating that CGP35348 is not a partial GABA(B) agonist in this experimental system. CGP54626, an extremely potent antagonist, exhibited only a minimal intrinsic activity. SCH50911, a GABA(B) antagonist belonging to a different chemical class, was devoid of significant activity, while phaclofen was effective only at 100-300 microM. In synaptosomes purified from the spinal cord or the hippocampus of mice lacking either the GABA(B1) (GABA(B1-/-) mice) or the GABA(B2) (GABA(B2-/-) mice) subunit, the evoked exocytosis of [(3)H]glycine was no longer inhibited by (-)-baclofen, whereas the intrinsic activity of CGP35348 and CGP52432 was not decreased. Activation of unknown sites on glycinergic terminals is likely to be involved. These unexpected effects should not be ignored when interpreting results obtained with the above GABA(B) receptor antagonists.

Nicotinic and muscarinic cholinergic receptors coexist on GABAergic nerve endings in the mouse striatum and interact in modulating GABA release.

Muscarinic cholinergic receptors (mAChRs) and nicotinic cholinergic receptors (nAChRs) regulating GABA release from striatal nerve endings were studied by monitoring release of previously accumulated [(3)H]GABA or endogenous GABA from superfused mouse striatal synaptosomes. Oxotremorine inhibited the release of [(3)H]GABA elicited by depolarization with 4-aminopyridine (4-AP), an effect antagonized by atropine. Agonists at nAChRs, including the alpha(4)beta(2)( *) subunit-selective RJR2403, provoked the release of [(3)H]GABA as well as of the endogenous transmitter; these effects also were prevented by oxotremorine and pilocarpine suggesting coexpression of functional mAChRs and alpha(4)beta(2)( *) nAChRs on GABAergic nerve endings. The inhibitory effects of oxotremorine on the release of [(3)H]GABA evoked by 4-AP or by RJR2403 were: (i) prevented by the M(2)/M(4) mAChR antagonist himbacine; (ii) insensitive to the M2 antagonist AFDX116; (iii) blocked by the selective M(4) mAChR antagonists MT3, thus indicating the involvement of receptors of the M(4) subtype. In conclusion, in the corpus striatum, acetylcholine released from cholinergic interneurons can activate alpha(4)beta(2)( *) nAChRs mediating release of GABA; this evoked release can be negatively modulated by M(4) mAChRs coexpressed on the same GABAergic terminals.

Glycinergic nerve endings in hippocampus and spinal cord release glycine by different mechanisms in response to identical depolarizing stimuli.

Studies on hippocampal glycine release are extremely rare. We here investigated release from mouse hippocampus glycinergic terminals selectively pre-labelled with [(3)H]glycine through transporters of the GLYT2 type. Purified synaptosomes were incubated with [(3)H]glycine in the presence of the GLYT1 blocker NFPS to abolish uptake (approximately 30%) through GLYT1. The non-GLYT1-mediated uptake was entirely sensitive to the GLYT2 blocker Org25543. Depolarization during superfusion with high-K(+) (15-50 mmol/L) provoked overflows totally dependent on external Ca(2+), whereas in the spinal cord the 35 or 50 mmol/L KCl-evoked overflow (higher than that in hippocampus) was only partly dependent on extraterminal Ca(2+). In the hippocampus, the Ca(2+)-dependent 4-aminopyridine (1 mmol/L)-evoked overflow was five-fold lower than that in spinal cord. The component of the 10 mumol/L veratridine-induced overflow dependent on external Ca(2+) was higher in the hippocampus than that in spinal cord, although the total overflow in the hippocampus was only half of that in the spinal cord. Part of the veratridine-evoked hippocampal overflow occurred by GLYT2 reversal and part by bafilomycin A(1)-sensitive exocytosis dependent on cytosolic Ca(2+) generated through the mitochondrial Na(+)/Ca(2+) exchanger. As glycine sites on NMDA receptors are normally not saturated, understanding mechanisms of glycine release should facilitate pharmacological modulation of NMDA receptor function.

Functional expression of release-regulating glycine transporters GLYT1 on GABAergic neurons and GLYT2 on astrocytes in mouse spinal cord.

It is widely accepted that glycine transporters of the GLYT1 type are situated on astrocytes whereas GLYT2 are present on glycinergic neuronal terminals where they mediate glycine uptake. We here used purified preparations of mouse spinal cord nerve terminals (synaptosomes) and of astrocyte-derived subcellular particles (gliosomes) to characterize functionally and morphologically the glial versus neuronal distribution of GLYT1 and GLYT2. Both gliosomes and synaptosomes accumulated [3H]GABA through GAT1 transporters and, when exposed to glycine in superfusion conditions, they released the radioactive amino acid not in a receptor-dependent manner, but as a consequence of glycine penetration through selective transporters. The glycine-evoked release of [3H]GABA was exocytotic from synaptosomes but GAT1 carrier-mediated from gliosomes. Based on the sensitivity of the glycine effects to selective GLYT1 and GLYT2 blockers, the two transporters contributed equally to evoke [3H]GABA release from GABAergic synaptosomes; even more surprising, the 'neuronal' GLYT2 contributed more efficiently than the 'glial' GLYT1 to mediate the glycine effect in [3H]GABA releasing gliosomes. These functional results were largely confirmed by confocal microscopy analysis showing co-expression of GAT1 and GLYT2 in GFAP-positive gliosomes and of GAT1 and GLYT1 in MAP2-positive synaptosomes. To conclude, functional GLYT1 are present on neuronal axon terminals and functional GLYT2 are expressed on astrocytes, indicating not complete selectivity of glycine transporters in their glial versus neuronal localization in the spinal cord.

Mechanisms of [(3)H]glycine release from mouse spinal cord synaptosomes selectively labeled through GLYT2 transporters.

Glycine release has been rarely studied. The aim of this work was to characterize the release of the amino acid from spinal cord glycinergic nerve endings selectively pre-labeled through glycine transporters of the GLYT2 type. Purified mouse spinal cord synaptosomes were incubated with [(3)H]glycine in the presence of the GLYT1 blocker N-[(3R)-3-([1,1'-biphenyl]-4-yloxy)-3-(4-fluorophenyl)propyl]-N-methylglycine hydrochloride and exposed in superfusion to varying concentrations of KCl, 4-aminopyridine (4-AP), or veratridine. KCl (< or = 15 micromol/L), 4-AP (up to 1 mmol/L), and veratridine (< or = 0.3 micromol/L)-provoked [(3)H]glycine release by external Ca2+-dependent, botulinum toxin C(1)-sensitive, exocytosis. The overflows evoked by higher concentrations of K+ or veratridine involved external Ca2+-independent mechanisms of different nature. Only the overflow evoked by 3 or 10 micromol/L veratridine occurred totally (3 micromol/L) or in part (10 micromol/L) by transporter reversal, being sensitive to the GLYT2 blockers 4-benzyloxy-3,5-dimethoxy-N-[1-(dimethylaminociclopentyl)-methyl] benzamide or O-[(2-benzyloxyphenyl-3-flurophenyl)methyl]-l-serine; in contrast, the external Ca2+-independent [(3)H]glycine overflow provoked by 50 mmol/L K+ was transporter-independent. This component of K+-evoked overflow and the GLYT2-independent portion of the 10 micromol/L veratridine-evoked overflow, were largely sensitive to the vesicle depletor bafilomycin or BAPTA-AM and were prevented by blocking the mitochondrial Na+/Ca2+ exchanger with 7-chloro-5-(2-chlorophenyl)-1,5-dihydro-4,1-benzothiazepin-2(3H)-one, indicating the involvement of exocytosis triggered by intraterminal mitochondrial Ca2+ ions.

Antidepressant treatments and function of glutamate ionotropic receptors mediating amine release in hippocampus.

Previous evidences showed that, besides noradrenaline (NA) and 5-hydroxytryptamine (5-HT), glutamate transmission is involved in the mechanism of action of antidepressants (ADs), although the relations between aminergic and glutamatergic systems are poorly understood. The aims of this investigation were to evaluate changes in the function of glutamate AMPA and NMDA receptors produced by acute and chronic administration of the two ADs reboxetine and fluoxetine, selective inhibitors of NA and 5-HT uptake, respectively. Rats were treated acutely (intraperitoneal injection) or chronically (osmotic minipump infusion) with reboxetine or fluoxetine. Isolated hippocampal nerve endings (synaptosomes) prepared following acute/chronic treatments were labelled with [(3)H]NA or [(3)H]5-HT and [(3)H]amine release was monitored during exposure in superfusion to NMDA/glycine, AMPA or K(+)-depolarization. Acute and chronic reboxetine reduced the release of [(3)H]NA evoked by NMDA/glycine or by AMPA. The NMDA/glycine-evoked release of [(3)H]NA was also down-regulated by chronic fluoxetine. Only acute, but not chronic, fluoxetine inhibited the AMPA-evoked release of [(3)H]5-HT. The release of [(3)H]NA and [(3)H]5-HT elicited by K(+)-depolarization was almost abolished by acute reboxetine or fluoxetine, respectively, but recovered during chronic ADs administration. ADs reduced NMDA receptor-mediated releasing effects in noradrenergic terminals after acute and chronic administration, although by different mechanisms. Chronic treatments markedly reduced the expression level of NR1 subunit in synaptic membranes. The noradrenergic and serotonergic release systems seem to be partly functionally interconnected and interact with glutamatergic transmission to down-regulate its function. The results obtained support the view that glutamate plays a major role in AD activity.

Evidence that alpha7 nicotinic receptor modulates glutamate release from mouse neocortical gliosomes.

The presence of nicotinic receptors on astrocytes in human and rat brain has been previously demonstrated however their possible functional role is still poorly understood. In this study we investigated on the presence of nicotinic receptors on gliosomes, purified from mouse cortex, and on their role in eliciting glutamate release. Epibatidine significantly increased basal release of [3H]D-aspartate and of endogenous glutamate from mouse gliosomes but not from synaptosomes. This effect was prevented by methyllycaconitine, alpha-bungarotoxin and mecamylamine but not by dihydro-beta-erythroidine. Epibatidine provoked also a significant increase of calcium concentration in gliosomes but not in synaptosomes; the increase in [Ca2+]i induced by epibatidine and KCl in gliosomes was very similar to each other. The present results indicate that alpha7 nicotinic receptors exist on mouse cortical glial particles and stimulate glutamate release.

The GABAergic-like system in the marine demosponge Chondrilla nucula.

Gamma-amino butyric acid (GABA) is believed to be the principal inhibitory neurotransmitter in the mammalian central nervous system, a function that has been extended to a number of invertebrate systems. The presence of GABA in the marine demosponge Chondrilla nucula was verified using immunofluorescence detection and high-pressure liquid chromatography. A strong GABA-like immunoreactivity (IR) was found associated with choanocytes, exopinacocytes, endopinacocytes lining inhalant, and exhalant canals, as well as in archaeocytes scattered in the mesohyl. The capacity to synthesize GABA from glutamate and to transport it into the vesicles was confirmed by the presence in C. nucula of glutamate decarboxylase (GAD) and vesicular GABA transporters (vGATs), respectively. GAD-like and vGAT-like IR show the same distribution as GABA-like IR. Supporting the similarity between sponge and mammalian proteins, bands with an apparent molecular weight of about 65-67 kDa and 57 kDa were detected using antibodies raised against mammalian GAD and vGAT, respectively. A functional metabotropic GABA(B)-like receptor is also present in C. nucula. Indeed, both GABA(B) R1 and R2 isoforms were detected by immunoblot and immunofluorescence. Also in this case, IR was found in choanocytes, exopinacocytes, and endopinacocytes. The content of GABA in C. nucula amounts to 1225.75 +/- 79 pmol/mg proteins and GABA is released into the medium when sponge cells are depolarized. In conclusion, this study is the first indication of the existence of the GABA biosynthetic enzyme GAD and of the GABA transporter vGAT in sponges, as well as the first demonstration that the neurotransmitter GABA is released extracellularly.

Chronic antidepressants reduce depolarization-evoked glutamate release and protein interactions favoring formation of SNARE complex in hippocampus.

Glutamate neurotransmission was recently implicated in the action of stress and in antidepressant mechanisms. We report that chronic (not acute) treatment with three antidepressants with different primary mechanisms (fluoxetine, reboxetine, and desipramine) markedly reduced depolarization-evoked release of glutamate, stimulated by 15 or 25 mm KCl, but not release of GABA. Endogenous glutamate and GABA release was measured in superfused synaptosomes, freshly prepared from hippocampus of drug-treated rats. Interestingly, treatment with the three drugs only barely changed the release of glutamate (and of GABA) induced by ionomycin. In synaptic membranes of chronically treated rats we found a marked reduction in the protein-protein interaction between syntaxin 1 and Thr286-phosphorylated alphaCaM kinase II (alpha-calcium/calmodulin-dependent protein kinase II) (an interaction previously proposed to promote neurotransmitter release) and a marked increase in the interaction between syntaxin 1 and Munc-18 (an interaction proposed to reduce neurotransmitter release). Furthermore, we found a selective reduction in the expression level of the three proteins forming the core SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) complex. These findings suggest that antidepressants work by stabilizing glutamate neurotransmission in the hippocampus and that they may represent a useful tool for the study of relationship between functional and molecular processes in nerve terminals.

Co-existence of GABA and Glu transporters in the central nervous system.

Co-localization of transporters able to recapture the released or endogenously synthesized transmitter (homotransporters) and of transporters that can selectively take up transmitters/modulators originating from neighbouring structures (heterotransporters) has been demonstrated to occur within the same axon terminal of several neuronal phenotypes. Activation of terminal heterotransporters invariably leads to the release of the transmitter specific to the terminal. Heterotransporters are also increasingly reported to exist on neuronal soma/dendrites and nerve terminals, on the basis of morphological experiments. The functions of somatodendritic heterotransporters has been investigated only in a very limited number of cases. Release-regulating GABA heterotransporters of the GAT-1 type exist on Glu nerve terminals in different rodent brain regions including spinal cord. Activation of GABA heterotransporters provokes release of Glu, which takes place by reversal of the Glu homotransporter and by anion channel opening. Interestingly, the release of Glu induced by GABA in spinal cord is dramatically enhanced in a transgenic mouse model of amyotrophic lateral sclerosis and this effect seems to represent the most precocious mechanism that increases extracellular Glu concentration, reported to occur in the pathomechanism.

P2X(7) receptors exert a permissive role on the activation of release-enhancing presynaptic alpha7 nicotinic receptors co-existing on rat neocortex glutamatergic terminals.

Adenosine triphosphate (ATP) has been reported to enhance the release of glutamate by acting at P2X presynaptic receptors. Acetylcholine (ACh) can elicit glutamate release through presynaptic nicotinic cholinergic receptors (nAChRs) of the alpha7 subtype situated on glutamatergic axon terminals, provided that the terminal membrane is weakly depolarized. Considering that ATP and ACh are co-transmitters, we here investigate on the possibility that P2X and nAChRs co-exist and interact on the same glutamatergic nerve endings using purified rat neocortex synaptosomes in superfusion. ATP evoked Ca(2+)-dependent release of pre-accumulated D-[(3)H]aspartate ([(3)H]D-ASP) as well as of endogenous glutamate; (-)-nicotine, inactive on its own, potentiated the ATP-evoked release. The ATP analogue benzoylbenzoylATP (BzATP) behaved like ATP, but was approximately 30 times more potent; the potentiation of the BzATP-evoked release was blocked by methyllycaconitine or alpha-bungarotoxin. Adding inactive concentrations of (-)-nicotine, epibatidine or choline together with inactive concentrations of BzATP resulted in significant elevation of the [(3)H]D-ASP release mediated by alpha7 nAChRs. To conclude, P2X(7) receptors and alpha7 nAChRs seem to co-exist and interact on rat neocortex glutamatergic terminals; in particular, P2X(7) receptors exert a permissive role on the activation of alpha7 nAChRs, suggesting that ATP may not only evoke glutamate release on its own, but may also regulate the release of the amino acid elicited by ACh.

Coexistence and function of different neurotransmitter transporters in the plasma membrane of CNS neurons.

Transporters able to recapture released neurotransmitters into neurons can no longer be considered as cell-specific neuronal markers. In fact, colocalization on one nerve terminal of transporters able to selectively recapture the released endogenously synthesized transmitter (homotransporters) and of transporters that can selectively take up transmitters/modulators originating from neighboring structures (heterotransporters) has been demonstrated to occur on several families of nerve terminals. Activation of heterotransporters often increases the release of the transmitter stored in the terminals on which the heterotransporters are localized. The release caused by heterotransporter activation takes place through multiple mechanisms including exocytosis, either dependent on external Ca(2+) or on Ca(2+) mobilized from intraterminal stores, and homotransporter reversal. Homocarrier-mediated release elicited by heterocarrier activation represents a clear case of transporter-transporter interaction. Although the functional significance of transporter coexpression on one nerve terminal remains to be established, it may in some instances reflect cotransmission. In other cases, heterotransporters may mediate modulation of basal transmitter release in addition to the modulation of the evoked release brought about by presynaptic heteroreceptors. Heterotransporters are also increasingly reported to exist on neuronal soma/dendrites. With the exception of EAAT4, the glutamate transporter/chloride channel situated on GABAergic Purkinje cells in the cerebellum, the functions of somatodendritic heterocarriers is not understood.

Advances in understanding the functions of native GlyT1 and GlyT2 neuronal glycine transporters.

Glycine can be substrate for two transporters: GlyT1, largely expressed by astrocytes but also by some non-glycinergic neurons, and GlyT2, most frequently present in glycine-storing nerve endings. In morphological studies, GlyT2 expression had been found to be restricted to caudal regions, being almost undetectable in neocortex and hippocampus. Here, we compared the uptake activities of GlyT1 and GlyT2 in synaptosomes purified from mouse spinal cord, cerebellum, neocortex and hippocampus. Although, as expected, [(3)H]glycine uptake was significantly lower in telencephalic than in caudal regions, selective GlyT2-mediated uptake could be evaluated in all areas. Appropriately, [(3)H]glycine selectively taken up into hippocampal synaptosomes through GlyT2 could be subsequently released by exocytosis. Native GlyT2, which did not contribute to basal release from cerebellum or spinal cord nerve terminals, could mediate release of [(3)H]glycine by transporter reversal in synaptosomes exposed to veratridine. Moreover, GlyT2 transporters could perform Na(+)-dependent homoexchange in response to externally added glycine. In conclusion, transporters of the GlyT2 type exhibited significant uptake also in telencephalic regions, probably because of the elevated driving force related to their stoichiometry. Although glycine release through GlyT2 had been predicted to be a very difficult process, GlyT2 expressed on isolated glycinergic nerve terminals can perform both release by transporter reversal and homoexchange.