Zn2+ modulation of neurotransmitter transporters

Neurotransmitter transporters located at the presynaptic or glial cell membrane are responsible for the stringent and rapid clearance of the transmitter from the synapse, and hence they terminate signaling and control the duration of synaptic inputs in the brain. Two distinct families of neurotransmitter transporters have been identified based on sequence homology: (1) the neurotransmitter sodium symporter family (NSS), which includes the Na+/C1(-)-dependent transporters for dopamine, norepinephrine, and serotonin; and (2) the dicarboxylate/amino acid cation symporter family (DAACS), which includes the Na(+)-dependent glutamate transporters (excitatory amino acid transporters; EAAT). In this chapter, we describe how the identification of endogenous Zn2(+)-binding sites, as well as engineering of artificial Zn2(+)-binding sites both in the Na+/Cl(-)-dependent transporters and in the EAATs, have proved to be an important tool for studying the molecular function of these proteins. We also interpret the current available data on Zn2(+)-binding sites in the context of the recently published crystal structures. Moreover, we review how the identification of endogenous Zn2(+)-binding sites has indirectly suggested the possibility that several of the transporters are modulated by Zn2+ in vivo, and thus that Zn2+ can play a role as a neuromodulator by affecting the function of neurotransmitter transporters.     

Inhibitor of the glutamate vesicular transporter (VGLUT)

The vesicular glutamate transporter (VGLUT) is responsible for the uptake of the excitatory amino acid, L-glutamate, into synaptic vesicles. VGLUT activity is coupled to an electrochemical gradient driven by a vacuolar ATPase and stimulated by low Cl-. VGLUT has relatively low affinity (K(m) = 1-3 mM) for glutamate and is pharmacologically and structurally distinct from the Na+-dependent, excitatory amino acid transporters (EAATs) found on the plasma membrane. Because glutamatergic neurotransmission begins with vesicular release, compounds that block the uptake of glutamate into the vesicle may reduce excitotoxic events. Several classes of competitive VGLUT inhibitors have emerged including amino acids and amino acid analogs, fatty acids, azo dyes, quinolines and alkaloids. The potency with which these agents inhibit VGLUT varies from millimolar (amino acids) to nanomolar (azo dyes) concentrations. These inhibitors represent highly diverse structures and have collectively begun to reveal key pharmacophore elements that may elucidate the key interactions important to binding VGLUT. Using known inhibitor structures and preliminary molecular modeling, a VGLUT pharmacophore is presented that will aid in the design of new, highly potent and selective agents.     

Glutamate transporters as drug targets

The L-glutamate (Glu) has been hypothesized as an excitatory amino acid neurotransmitter in the mammalian central nervous system after successful cloning and identification of a number of genes encoding signaling machineries required for the neurocrine at synapses in the brain. These include excitatory amino acid transporters (EAATs) for signal termination and vesicular Glu transporters (VGLUTs) for signal output through exocytotic release, in addition to Glu receptors (GluRs) for signal input. These Glu signaling molecules not only play key roles in mechanisms associated with synaptic plasticity such as learning and memory, but also participate in the etiology and pathology of different neuropsychiatric disorders and neuronal cell death seen in various neurodegenerative diseases. Of the aforementioned Glu signaling molecules, EAATs are essential for the termination of signal transmission mediated by Glu as well as for the prevention of neurotoxicity mediated by this endogenous excitotoxin, while VGLUTs are crucial for the storage of Glu in synaptic vesicles to suffice for the definition of a glutamatergic phenotype. Many early desperate efforts were devoted to the search and development of novel compounds with a therapeutic window toward GluRs, while relatively little attention was paid to either EAATs or VGLUTs in this aspect. In this review, therefore, we will summarize the classification and functionality of EAATs and VGLUTs with a focus on their possibilities as potential therapeutic targets for different neurodegenerative and neuropsychiatric disorders related to malfunction of Glu signaling in human beings.     

囊泡谷氨酸转运体与神经系统疾病

囊泡谷氨酸转运体(vesicular glutamate transporters,VGLUTs)能特异地装载谷氨酸进入突触囊泡并促进释放,它包括3个成员,其中VGLUT1和VGLUT2是谷氨酸能神经元和它们轴突末端高度特异的标志,同时VGLUT1标志着皮质-皮质投射,VGLUT2标志着丘脑-皮层投射。而VGLUT3则会出现在胆碱能中间神经元、5-羟色胺能神经元、海马和皮层中GABA能中间神经元中。VGLUTs的异常会导致兴奋性神经递质谷氨酸的异常,从而诱发多种神经系统疾病。该文综述了VGLUTs的功能障碍与阿尔采末病(Alzheimer’sdisease,AD)、帕金森病(Parkinson’s disease,PD)、精神分裂症、抑郁症、癫痫、耳聋发病的关系的研究进展,为这些疾病的防治提供新的线索。     

Expression of GFP-tagged neuronal glutamate transporters in cerebellar Purkinje neurons

Of the five excitatory amino acid transporters (EAATs) identified, two genes are expressed by neurons (EAAT3 and EAAT4) and give rise to transporters confined to neuronal cell bodies and dendrites. At an ultrastructural level, EAAT3 and EAAT4 proteins are clustered at the edges of postsynaptic densities of excitatory synapses. This pattern of localization suggests that postsynaptic EAATs may help to limit spillover of glutamate from excitatory synapses. In an effort to study transporter localization in living neurons and ultimately to manipulate uptake at intact synapses, we have developed viral reagents encoding neuronal EAATs tagged with GFP. We demonstrate that these fusion proteins are capable of Na(+)-dependent glutamate uptake, that they generate ionic conductances indistinguishable from their wild-type counterparts, and that GFP does not alter their glutamate dose-dependence. Two-photon microscopy was used to examine fusion protein expression in Purkinje neurons in acute cerebellar slices. Both EAAT3-GFP and EAAT4-GFP were observed at high levels in the dendritic spines of transfected Purkinje neurons. These findings indicate that functional EAAT fusion proteins can be synthesized and appropriately trafficked to postsynaptic compartments. Furthermore, they validate a powerful system for looking at EAAT function in situ.     

Neuronal high-affinity sodium-dependent glutamate transporters (EAATs): targets for the development of novel therapeutics against neurodegenerative diseases

L-Glutamate is the major excitatory neurotransmitter in mammalian central nervous system, and excitatory amino acid transporters (EAATs) are essential for terminating synaptic excitation and for maintaining extracellular glutamate concentration below toxic levels. Although the structure of these channel-like proteins has not been yet reported, their membrane topology has been hypothesised based on biochemical and protein sequence analyses. In the case of an inadequate clearance from synaptic cleft and from the extrasynaptic space, glutamate behaves as a potent neurotoxin, and it may be related to several neurodegenerative pathologies including epilepsy, ischemia, amyotrophic lateral sclerosis, and Alzheimer disease. The recent boom of glutamate is demonstrated by the enormous amount of publications dealing with the function of glutamate, with its role on modulation of synaptic transmission throughout the brain, mainly focusing: i). on the structure of its receptors, ii). on molecular biology and pharmacology of Glu transporters, and iii). on the role of glutamate uptake and reversal uptake in several neuropathologies. This review will deal with the recent and most interesting published results on Glu transporters membrane topology, Glu transporters physiopathological role and Glu transporters medicinal chemistry, highlighting the guidelines for the development of potential neuroprotective agents targeting neuronal high-affinity sodium-dependent glutamate transporters.     

Characterization of the tritium-labeled analog of L-threo-beta-benzyloxyaspartate binding to glutamate transporters

L-Glutamate is the major excitatory neurotransmitter in the mammalian central nervous system. Termination of glutamate receptor activation and maintenance of low extracellular glutamate concentrations are primarily achieved by glutamate transporters (excitatory amino acid transporters 1-5, EAATs1-5) located on both the nerve endings and the surrounding glial cells. To identify the physiological roles of each subtype, subtype-selective EAAT ligands are required. In this study, we developed a binding assay system to characterize EAAT ligands for all EAAT subtypes. We recently synthesized novel analogs of threo-beta-benzyloxyaspartate (TBOA) and reported that they blocked glutamate uptake by EAATs 1-5 much more potently than TBOA. The strong inhibitory activity of the TBOA analogs suggested that they would be suitable to use as radioisotope-labeled ligands, and we therefore synthesized a tritiated derivative of (2S,3S)-3-{3-[4-ethylbenzoylamino]benzyloxy}aspartate ([3H]ETB-TBOA). [3H]ETB-TBOA showed significant high-affinity specific binding to EAAT-transfected COS-1 cell membranes with each EAAT subtype. The Hill coefficient for the Na+-dependence of [3H]ETB-TBOA binding revealed a single class of noncooperative binding sites for Na+, suggesting that Na+ binding in the ligand binding step is different from Na+ binding in the substrate uptake process. The binding was displaced by known substrates and blockers. The rank order of inhibition by these compounds was consistent with glutamate uptake assay results reported previously. Thus, the [3H]ETB-TBOA binding assay will be useful to screen novel EAAT ligands for all EAAT subtypes.     

Parawixin1: a spider toxin opening new avenues for glutamate transporter pharmacology

Glutamate is the major excitatory neurotransmitter in the mammalian central nervous system. After release from glutamatergic nerve terminals, glial and neuronal glutamate transporters remove glutamate from the synaptic cleft to terminate synaptic transmission and to prevent neuronal damage by excessive glutamate receptor activation. In this issue of Molecular Pharmacology, Fontana et al. (p. 1228) report on the action of a venom compound, Parawixin1, on excitatory amino acid transporters (EAATs). They demonstrate that this agent selectively affects a glial glutamate transporter, EAAT2, by specifically increasing one particular step of the glutamate uptake cycle. Disturbed glutamate homeostasis seems to be a pathogenetic factor in several neurodegenerative disorders. Because EAAT2 is a key player in determining the extracellular glutamate concentration in the mammalian brain, drugs targeting this protein could prevent glutamate excitotoxicity without blocking glutamatergic transmission. Its specificity and selectivity makes Parawixin1 a perfect starting point to design small molecules for the treatment of pathological conditions caused by alterations of glutamate homeostasis.     

Characterization of novel L-threo-beta-benzyloxyaspartate derivatives, potent blockers of the glutamate transporters

Nontransportable blockers of the glutamate transporters are important tools for investigating mechanisms of synaptic transmission. DL-threo-beta-Benzyloxyaspartate (DL-TBOA) is a potent blocker of all subtypes of the excitatory amino acid transporters (EAATs). We characterized novel L-TBOA analogs possessing a substituent on their respective benzene rings. The analogs significantly inhibited labeled glutamate uptake, the most potent of which was (2S,3S)-3-[3-[4-(trifluoromethyl)benzoylamino]benzyloxy]aspartate (TFB-TBOA). In an uptake assay using cells transiently expressing EAATs, the IC(50) values of TFB-TBOA for EAAT1, EAAT2, and EAAT3 were 22, 17, and 300 nM, respectively. TFB-TBOA was significantly more potent at inhibiting EAAT1 and EAAT2 compared with L-TBOA (IC(50) values for EAAT1-3 were 33, 6.2, and 15 microM, respectively). Electrophysiological analyses revealed that TBOA analogs block the transport-associated currents in all five EAAT subtypes and also block leak currents in EAAT5. The rank order of the analogs for potencies at inhibiting substrate-induced currents was identical to that observed in the uptake assay. However, the kinetics of TFBTBOA differed from the kinetics of L-TBOA, probably because of the strong binding affinity. Notably, TFB-TBOA did not affect other representative neurotransmitter transporters or receptors, including ionotropic and metabotropic glutamate receptors, indicating that it is highly selective for EAATs. Moreover, intracerebroventricular administration of the TBOA analogs induced severe convulsive behaviors in mice, probably because of the accumulation of glutamate. Taken together, these findings indicate that novel TBOA analogs, especially TFB-TBOA, should serve as useful tools for elucidating the physiological roles of the glutamate transporters.     

Lessons from the knocked-out glycine transporters

Glycine has multiple neurotransmitter functions in the central nervous system (CNS). In the spinal cord and brainstem of vertebrates, it serves as a major inhibitory neurotransmitter. In addition, it participates in excitatory neurotransmission by modulating the activity of the N-methyl-D-aspartate (NMDA) subtype of glutamate receptors. The extracellular concentrations of glycine are regulated by Na+/Cl(-)-dependent glycine transporters (GlyTs), which are expressed in neurons and adjacent glial cells. Considerable progress has been made recently towards elucidating the in vivo roles of GlyTs in the CNS. The generation and analysis of animals carrying targeted disruptions of GlyT genes (GlyT knockout mice) have allowed investigators to examine the different contributions of individual GlyT subtypes to synaptic transmission. In addition, they have provided animal models for two hereditary human diseases, glycine encephalopathy and hyperekplexia. Selective GlyT inhibitors have been shown to modulate neurotransmission and might constitute promising therapeutic tools for the treatment of psychiatric and neurological disorders such as schizophrenia and pain. Therefore, pharmacological and genetic studies indicate that GlyTs are key regulators of both glycinergic inhibitory and glutamatergic excitatory neurotransmission. This chapter describes our present understanding of the functions of GlyTs and their involvement in the fine-tuning of neuronal communication.     

The diverse roles of vesicular glutamate transporter 3

The expression of vesicular glutamate transporters (VGLUTs) 1 and 2 accounts for the ability of most traditionally accepted excitatory neurons to release glutamate by exocytosis. However, several cell populations (serotonin and dopamine neurons) have been demonstrated to release glutamate in vitro and do not obviously express these transporters. Rather, these neurons express a novel, third isoform that in fact appears confined to neurons generally associated with a transmitter other than glutamate. They include serotonin and possibly dopamine neurons, cholinergic interneurons in the striatum, and GABAergic interneurons of the hippocampus and cortex. Although the physiological role of VGLUT3 remains largely conjectural, several observations in vivo suggest that the glutamate release mediated by VGLUT3 has an important role in synaptic transmission, plasticity, and development.     

Molecular pharmacology of the Na+-dependent transport of acidic amino acids in the mammalian central nervous system

The Na+-dependent transport of L-glutamate (GluT) has been identified in brain tissue more than thirty years ago. Neurochemical studies, performed in various experimental models during 1970's, defined the basic rules for the selection or synthesis of GluT-specific substrates and inhibitors. The protein molecules (transporters) that mediate the translocation of the substrates across the plasma membrane have been cloned and studied during the last ten years. The sites on the transporters that bind the substrates favour glutamate-like or aspartate-like molecules with one positively charged and two negatively charged ionised groups. Substituents at C3 and C4 are often tolerated but substitutions at C2 or alterations of the ionisable groups usually impede the binding. The substrate binding sites display an "anomalous" selectivity towards stereoisomers. These structural requirements are shared by all Na+-dependent glutamate transporters thus making the design of transporter-selective ligands a challenging task. Moreover, the molecular mechanisms of the transport have not yet been adequately elucidated. Data from a wide variety of experimental studies strongly indicate that Na+-dependent GluT regulates the functioning of the glutamatergic excitatory synapses-the most important rapid inter-neuronal signalling system in the mammalian brain. Altered structural and/or functional properties of the Na+-dependent glutamate transporters have been implicated in the damage to the brain tissue following cerebral ischaemia and in the progressive loss of neurons in conditions such as Alzheimer dementia and amyotrophic lateral sclerosis. Furthermore, it seems that fine-tuning of glutamatergic neurotransmission by regulating the Na+-dependent GluT could be useful in the therapy of schizophrenia.     

Pharmacological manipulation of glutamate transport

L-Glutamic acid acts as the major excitatory neurotransmitter and, at the same time, represents a potential neurotoxin for the mammalian central nervous system (CNS). The termination of excitatory transmission and the maintenance of physiologic levels of extracellular glutamate, which is necessary to prevent excitotoxicity, are prominently mediated by a family of high-affinity sodium-dependent excitatory amino acid transporters (EAATs). Five subtypes of EAATs have been cloned, possessing distinct pharmacology, localization, sensitivity to transport inhibitors and modulatory mechanisms. Expression and activity of EAATs have been shown to be amenable to fine endogenous and, potentially, pharmacological regulation by substrate itself, growth factors, second messengers, hormones, biological oxidants, inflammatory mediators and pathological conditions. The present review describes basic pharmacological studies, mostly performed on animal models or cell preparations, in order to obtain an updated picture of the known regulatory mechanisms of single EAAT expression and activity. New insight into molecular pathways involved in EAAT regulation will allow pharmacological manipulation of excitatory CNS activity, possibly avoiding adverse effects of glutamate receptor blockade.     

The role of glial monoamine transporters in the central nervous system]

Monoamine transport systems play a very important role in determining the concentrations of monoamines in the synaptic cleft, and therefore the magnitude and duration of the effects of transmitters. Several transport systems for monoamines have been described. The first to be recognized were uptake, a Na(+)-dependent, high-affinity, cocaine-sensitive neuronal transporter, which includes dopamine transporter, norepinephrine transporter and serotonin transporter, and uptake1, a Na(+)-independent, low-affinity, high-capacity, steroid-sensitive extraneuronal transporter. Recently, molecular identification of the uptake2 transporter has been reported, and this has been called extraneuronal monoamine transporter in humans, and organic cation transporter3 in rats. Astrocytes contain these two transport systems that can remove monoamine neurotransmitters from the synaptic cleft by transporters present in the plasma membrane. Since monoamine oxidase and catechol-O-methyl-transferase are present in astroglial cells, their glial uptake systems are likely to play an important role in regulating extracellular monoamine concentrations. This uptake system may be characterized as a second line of defense that inactivates monoamines that have escaped neuronal re-uptake, and thus prevents uncontrolled spreading of the signal. In this review, the identification of monoamine transporters in astrocytes is described and the physiological role of glial monoamine transporters in monoaminergic neurotransmission is discussed.     

Chemo-enzymatic synthesis of (2S,4R)-2-amino-4-(3-(2,2-diphenylethylamino)-3-oxopropyl)pentanedioic acid: a novel selective inhibitor of human excitatory amino acid transporter subtype 2

In the mammalian central nervous system (CNS), the action of sodium dependent excitatory amino acid transporters (EAATs) is responsible for termination of glutamatergic neurotransmission by reuptake of ( S) -glutamate (Glu) from the synaptic cleft. Five EAAT subtypes have been identified, of which EAAT1-4 are present in the CNS, while EAAT5 is localized exclusively in the retina. In this study, we have used an enantioselective chemo-enzymatic strategy to synthesize 10 new Glu analogues 2a- k ( 2d is exempt) with different functionalities in the 4 R-position and characterized their pharmacological properties at the human EAAT1-3. In particular, one compound, 2k, displayed a significant preference as inhibitor of the EAAT2 subtype over EAAT1,3. The compound also displayed very low affinities toward ionotropic and metabotropic Glu receptors, making it the most selective EAAT2 inhibitor described so far.     

Cerebral cystine uptake: a tale of two transporters

Transport of cystine across the cell membrane is essential for synthesis of the major cellular antioxidant glutathione. Cystine uptake in the brain occurs by both the Na(+)-independent x(c)(-) cystine-glutamate exchanger and the X(AG)(-) family of high-affinity, Na(+)-dependent glutamate transporters. New evidence concerning the role of cystine transport in the defence against oxidative stress is described.     

Transporters for L-glutamate: an update on their molecular pharmacology and pathological involvement

L-Glutamate (Glu) is the major excitatory neurotransmitter in the mammalian CNS and five types of high-affinity Glu transporters (EAAT1-5) have been identified. The transporters EAAT1 and EAAT2 in glial cells are responsible for the majority of Glu uptake while neuronal EAATs appear to have specialized roles at particular types of synapses. Dysfunction of EAATs is specifically implicated in the pathology of neurodegenerative conditions such as amyotrophic lateral sclerosis, epilepsy, Huntington's disease, Alzheimer's disease and ischemic stroke injury, and thus treatments that can modulate EAAT function may prove beneficial in these conditions. Recent advances have been made in our understanding of the regulation of EAATs, including their trafficking, splicing and post-translational modification. This article summarises some recent developments that improve our understanding of the roles and regulation of EAATs.     

Excitatory amino acid transporters as emerging targets for central nervous system therapeutics

In the mammalian central nervous system (CNS) the excitatory amino acid transporter (EAAT) family of proteins are responsible for the high-affinity sodium-dependent uptake of glutamate into both astroglial cells and neurones. Normal EAAT function is required both for the efficient termination of glutamatergic neurotransmission and for the maintenance of low extracellular glutamate concentrations, thereby preventing glutamate excitotoxicity. It is widely believed that a dysfunction of glutamate transmission participates in the aetiology of a number of neurodegenerative and neuropsychiatric disorders and diseases. This review introduces the EAATs as a new family of emerging therapeutic targets for CNS disorders by virtue of their central role in maintaining glutamate homeostasis. We examine recent findings on the modulation and regulation of EAATs and review the changes in both EAAT function and expression which have been described in a number of neuropathological conditions.