Substrates and non-transportable analogues induce structural rearrangements at the extracellular entrance of the glial glutamate transporter GLT-1/EAAT2

To explore rearrangements of the reentrant loop HP2 relative to transmembrane domains (TMs) 7 and 8 during transport by the glial glutamate transporter GLT-1/EAAT2, cysteine pairs were introduced at the extracellular ends of these structural elements. The pairs were introduced around 10-15 A "above" the residues, which make contact with substrate in the related archaeal homologue Glt(Ph). Transport by the double mutants M449C/L466C (HP2/TM 8), L453C/I463C (HP2/TM 8), and I411C/I463C (TM 7/TM 8) was inhibited by copper(II)(1,10-phenanthroline)(3) (CuPh) and by Cd(2+). Inhibition was only observed when the two cysteines were present in the same construct, but not with the respective single cysteine mutants or when only one cysteine was paired with a mutation to another residue. Glutamate and potassium, both expected to increase the proportion of inward-facing transporters, significantly protected against the inhibition of transport activity of M449C/L466C by CuPh. The non-transportable analogues kainate and d, l-threo-beta-benzyloxyaspartate are expected to stabilize an outward-facing conformation, but only the latter potentiated the effect of CuPh on M449C/L466C. However, both analogues increased the aqueous accessibility of the cysteines introduced at positions 449 and 466 to a membrane-impermeant sulfhydryl reagent. Inhibition of L453C/I463C by CuPh was protected not only by glutamate but also by the two analogues. In contrast, these ligands had very little effect on the inhibition of I411C/I463C by CuPh. Our results are consistent with the proposal that HP2 serves as the extracellular gate of the transporter and indicate that glutamate and the two analogues induce distinct conformations of HP2.     

Position of the third Na+ site in the aspartate transporter GltPh and the human glutamate transporter, EAAT1

Glutamate transport via the human excitatory amino acid transporters is coupled to the co-transport of three Na(+) ions, one H(+) and the counter-transport of one K(+) ion. Transport by an archaeal homologue of the human glutamate transporters, Glt(Ph), whose three dimensional structure is known is also coupled to three Na(+) ions but only two Na(+) ion binding sites have been observed in the crystal structure of Glt(Ph). In order to fully utilize the Glt(Ph) structure in functional studies of the human glutamate transporters, it is essential to understand the transport mechanism of Glt(Ph) and accurately determine the number and location of Na(+) ions coupled to transport. Several sites have been proposed for the binding of a third Na(+) ion from electrostatic calculations and molecular dynamics simulations. In this study, we have performed detailed free energy simulations for Glt(Ph) and reveal a new site for the third Na(+) ion involving the side chains of Threonine 92, Serine 93, Asparagine 310, Aspartate 312, and the backbone of Tyrosine 89. We have also studied the transport properties of alanine mutants of the coordinating residues Threonine 92 and Serine 93 in Glt(Ph), and the corresponding residues in a human glutamate transporter, EAAT1. The mutant transporters have reduced affinity for Na(+) compared to their wild type counterparts. These results confirm that Threonine 92 and Serine 93 are involved in the coordination of the third Na(+) ion in Glt(Ph) and EAAT1.     

Thrombin-stimulated glutamate uptake in human platelets is predominantly mediated by the glial glutamate transporter EAAT2

Glutamate toxicity has been implicated in the pathogenesis of various neurological diseases. Glial glutamate transporters play a key role in the regulation of extracellular glutamate levels in the brain by removing glutamate from the extracellular fluid. Since human blood platelets possess an active glutamate uptake system, they have been used as a peripheral model of glutamate transport in the central nervous system (CNS). The present study is aimed at identifying the glutamate transporter on blood platelets, and to asses the influence of platelet activation on glutamate uptake. Platelets from healthy donors showed Na+-dependent glutamate uptake (Km, 3.5+/-0.9 microM; Vmax, 2.8+/-0.2 pmol glutamate/75 x 10(6)platelets/30 min), which could be blocked dose-dependently by the EAAT specific inhibitors DL-threo-E-benzyloxyaspartate (TBOA), L-trans-pyrrolidine-2,4-dicarboxylic acid (tPDC) and high concentrations of the EAAT2 inhibitor dihydrokainate (DHK). Analysis of platelet homogenates on Western blots showed EAAT2 as the predominant glutamate transporter. Platelet activation by thrombin caused an increase in glutamate uptake, which could be inhibited by TBOA and the EAAT2 inhibitor DHK. Kinetic analysis showed recruitment of new transporters to the membrane. Indeed, Western blot analysis of subcellular fractions revealed that alpha-granules, which fuse with the membrane upon thrombin stimulation, contained significant EAAT2 immunoreactivity. Inhibition of the second messengers involved in alpha-granule secretion (protein kinase C, phosphatidylinositol-3-kinase) inhibited thrombin-stimulated uptake, but not basal uptake. These data show that the glial EAAT2 is the predominant glutamate transporter on blood platelets and suggest, that thrombin increases glutamate uptake capacity by recruiting new transporters (EAAT2) from alpha-granules.     

Caspase-3 cleaves and inactivates the glutamate transporter EAAT2

EAAT2 is a high affinity, Na+-dependent glutamate transporter with predominant astroglial localization. It accounts for the clearance of the bulk of glutamate released at central nervous system synapses and therefore has a crucial role in shaping glutamatergic neurotransmission and limiting excitotoxicity. Caspase-3 activation and impairment in expression and activity of EAAT2 are two distinct molecular mechanisms occurring in human amyotrophic lateral sclerosis (ALS) and in the transgenic rodent model of the disease. Excitotoxicity caused by down-regulation of EAAT2 is thought to be a contributing factor to motor neuron death in ALS. In this study, we report the novel evidence that caspase-3 cleaves EAAT2 at a unique site located in the cytosolic C-terminal domain of the transporter, a finding that links excitotoxicity and activation of caspase-3 as converging mechanisms in the pathogenesis of ALS. Caspase-3 cleavage of EAAT2 leads to a drastic and selective inhibition of this transporter. Heterologous expression of mutant SOD1 proteins linked to the familial form of ALS leads to inhibition of EAAT2 through a mechanism that largely involves activation of caspase-3 and cleavage of the transporter. In addition, we found evidence in spinal cord homogenates of mutant SOD1 ALS mice of a truncated form of EAAT2, likely deriving from caspase-3-mediated proteolytic cleavage, which appeared concurrently to the loss of EAAT2 immunoreactivity and to increased expression of activated caspase-3. Taken together, our findings suggest that caspase-3 cleavage of EAAT2 is one mechanism responsible for the impairment of glutamate uptake in mutant SOD1-linked ALS.     

Neutralizing aspartate 83 modifies substrate translocation of excitatory amino acid transporter 3 (EAAT3) glutamate transporters

Excitatory amino acid transporters (EAATs) terminate glutamatergic synaptic transmission by removing glutamate from the synaptic cleft into neuronal and glial cells. EAATs are not only secondary active glutamate transporters but also function as anion channels. Gating of EAAT anion channels is tightly coupled to transitions within the glutamate uptake cycle, resulting in Na(+)- and glutamate-dependent anion currents. A point mutation neutralizing a conserved aspartic acid within the intracellular loop close to the end of transmembrane domain 2 was recently shown to modify the substrate dependence of EAAT anion currents. To distinguish whether this mutation affects transitions within the uptake cycle or directly modifies the opening/closing of the anion channel, we used voltage clamp fluorometry. Using three different sites for fluorophore attachment, V120C, M205C, and A430C, we observed time-, voltage-, and substrate-dependent alterations of EAAT3 fluorescence intensities. The voltage and substrate dependence of fluorescence intensities can be described by a 15-state model of the transport cycle in which several states are connected to branching anion channel states. D83A-mediated changes of fluorescence intensities, anion currents, and secondary active transport can be explained by exclusive modifications of substrate translocation rates. In contrast, sole modification of anion channel opening and closing is insufficient to account for all experimental data. We conclude that D83A has direct effects on the glutamate transport cycle and that these effects result in changed anion channel function.     

Two conformational changes are associated with glutamate translocation by the glutamate transporter EAAC1

Glutamate is transported across membranes by means of a carrier mechanism that is thought to require conformational changes of the transport protein. In this work, we have determined the thermodynamic parameters of glutamate and the Na+ binding steps to their extracellular binding sites along with the activation parameters of rapid, glutamate-induced processes in the transport cycle by analyzing the temperature dependence of glutamate transport at steady state and pre-steady state. Our results suggest that glutamate binding to the transporter is driven by a negative reaction enthalpy (DeltaH0 = -33 kJ/mol), whereas the tighter binding of the non-transportable inhibitor TBOA is caused by an additional increase in entropy. Processes linked to the binding of glutamate and Na+ to the transporter are associated with low activation barriers, indicative of diffusion-controlled reactions. The activation enthalpies of two processes in the glutamate translocation branch of the transport cycle were DeltaH++ = 95 kJ/mol and DeltaH++ = 120 kJ/mol, respectively. Such large values of DeltaH++ suggest that these processes are rate-limited by conformational changes of the transporter. We also found a large activation barrier for steady-state glutamate transport, which is rate-limited by the K+-dependent relocation of the empty transporter. Together, these results suggest that two conformational changes accompany glutamate translocation and at least one conformational change accompanies the relocation of the empty transporter. We interpret the data with an alternating access model that includes the closing and opening of an extracellular and an intracellular gate, respectively, in analogy to a hypothetical model proposed previously on the basis of the crystal structure of the bacterial glutamate transporter GltPh.     

岗田酸诱导大鼠脑神经细胞表达谷氨酸转运体EAAT1

为研究tau蛋白高度磷酸化与谷氨酸转运体功能之间的关系,实验采用免疫组织化学、荧光双标记技术及大鼠额叶皮质定位注射的方法,观察了蛋白磷酸酶抑制剂岗田酸（okadaic acid,OA)所致神经细胞退化对谷氨酸转运体亚型EAAT1表达的影响。结果如下：（1）在OA注射中心区神经元早期出现胞体固缩、肿胀、核移位,在注射3d时细胞破碎,发生坏死,并有大量炎性细胞浸润等病理现象;边周区细胞呈AT8（微管相关蛋白tau磷酸化指标）免疫阳性反应;（2）OA首先诱导神经细胞突起远端tau蛋白磷酸化,并逐渐向胞体发展,形成营养不良的神经细胞突起和神经纤维缠结样病理改变;（3）AT8免疫阳性反应脑区的神经细胞高表达谷氨酸转运体EAAT1,在12h阳性表达细胞数显著增多（P＜0．01）,1d时达峰值（P＜0．001）,3d时明显减少。在OA作用下EAAT1表达于星形胶质细胞和神经元。结果提示,OA致微管相关蛋白tau高度磷酸化时可诱导该区星形胶质细胞和神经元高表达谷氨酸转体EAAT1。EAAT1高表达的病理生理意义有待进一步的阐明。     

Regulation of the Na+-coupled glutamate transporter EAAT3 by PIKfyve

The Na⁺,glutamate cotransporter EAAT3 is expressed in a wide variety of tissues. It accomplishes transepithelial transport and the cellular uptake of acidic amino acids. Regulation of EAAT3 activity involves a signaling cascade including the phosphatidylinositol-3 (PI3)-kinase, the phosphoinositide dependent kinase PDK1, and the serum and glucocorticoid inducible kinase SGK1. Targets of SGK1 include the mammalian phosphatidylinositol-3-phosphate-5-kinase PIKfyve (PIP5K3). The present experiments explored whether PIKfyve participates in the regulation of EAAT3 activity. To this end, EAAT3 was expressed in Xenopus oocytes with or without SGK1 and/or PIKfyve and glutamate-induced current (I_glu) determined by dual electrode voltage clamp. In Xenopus oocytes expressing EAAT3 but not in water injected oocytes glutamate induced an inwardly directed I_glu. Coexpression of either, SGK1 or PIKfyve, significantly enhanced I_glu in EAAT3 expressing oocytes. The increased I_glu was paralleled by increased EAAT3 protein abundance in the oocyte cell membrane. I_glu and EAAT3 protein abundance were significantly larger in oocytes coexpressing EAAT3, SGK1 and PIKfyve than in oocytes expressing EAAT3 and either, SGK1 or PIKfyve, alone. Coexpression of the inactive SGK1 mutant ^K127NSGK1 did not significantly alter I_glu in EAAT3 expressing oocytes and completely reversed the stimulating effect of PIKfyve coexpression on I_glu. The stimulating effect of PIKfyve on I_glu was abolished by replacement of the serine by alanine in the SGK consensus sequence (^S318APIKfyve). Moreover, additional coexpression of ^S318APIKfyve significantly blunted I_glu in Xenopus oocytes coexpressing SGK1 and EAAT3. The observations demonstrate that PIKfyve participates in EAAT3 regulation likely downstream of SGK1.     

Loss of cell viability by histidine substitution of leucine 325 of the glutamate transporter EAAT1

Although glutamate transporters and neutral amino acid transporters have 55% amino acid identity in the transmembrane domains, many residues are still unique to individual transporters, providing for structural stability or substrate binding. In this study, the mutant protein L325H, which replaced a leucine 325 of the glutamate transporter EAAT1 by a histidine, was evaluated. When expressed in Xenopus oocytes, L325H caused oocytes to weaken pigmentation in the animal pole, accompanied by patches of colorless spots. Oocytes finally oozed cytoplasm. The resting membrane potential in L325H oocytes was -18.9 +/- 2.5 mV, significantly more positive than -37.3 +/- 2.5 mV of oocytes expressing EAAT1. The holding current at -60 mV was 283.1 +/- 48.3 nA in L325H oocytes and 92.2 +/- 12.6 nA in EAAT1 oocytes. These results suggest that even though glutamate and neutral amino acid transporters have strong overall homology, the local structure in the transmembrane domains may be different.     

Na(+)-dependent glutamate transporters (EAAT1, EAAT2, and EAAT3) of the blood-brain barrier. A mechanism for glutamate removal.

Na(+)-dependent transporters for glutamate exist on astrocytes (EAAT1 and EAAT2) and neurons (EAAT3). These transporters presumably assist in keeping the glutamate concentration low in the extracellular fluid of brain. Recently, Na(+)-dependent glutamate transport was described on the abluminal membrane of the blood-brain barrier. To determine whether the above-mentioned transporters participate in glutamate transport of the blood-brain barrier, total RNA was extracted from bovine cerebral capillaries. cDNA for EAAT1, EAAT2, and EAAT3 was observed, indicating that mRNA was present. Western blot analysis demonstrated all three transporters were expressed on abluminal membranes, but none was detectable on luminal membranes of the blood-brain barrier. Measurement of transport kinetics demonstrated voltage dependence, K(+)-dependence, and an apparent K(m) of 14 microM (aggregate of the three transporters) at a transmembrane potential of -61 mV. Inhibition of glutamate transport was observed using inhibitors specific for EAAT2 (kainic acid and dihydrokainic acid) and EAAT3 (cysteine). The relative activity of the three transporters was found to be approximately 1:3:6 for EAAT1, EAAT2, and EAAT3, respectively. These transporters may assist in maintaining low glutamate concentrations in the extracellular fluid.     

Regulation of the glutamate transporter EAAT3 by mammalian target of rapamycin mTOR

The serine/threonine kinase mammalian target of rapamycin (mTOR) is stimulated by insulin, growth factors and nutrients and confers survival of several cell types. The kinase has previously been shown to stimulate amino acid uptake. In neurons, the cellular uptake of glutamate by the excitatory amino-acid transporters (EAATs) decreases excitation and thus confers protection against excitotoxicity. In epithelia, EAAT3 accomplishes transepithelial glutamate and aspartate transport. The present study explored, whether mTOR regulates EAAT3 (SLC1A1). To this end, cRNA encoding EAAT3 was injected into Xenopus oocytes with or without cRNA encoding mTOR and the glutamate induced current (I(glu)), a measure of glutamate transport, determined by dual electrode voltage clamp. Moreover, EAAT3 protein abundance was determined utilizing chemiluminescence. As a result, I(glu) was observed in Xenopus oocytes expressing EAAT3 but not in water injected oocytes. Coexpression of mTOR significantly increased I(glu), an effect reversed by rapamycin (100 nM). mTOR coexpression increased EAAT3 protein abundance in the cell membrane. The decay of I(glu) following inhibition of carrier insertion with brefeldin A in oocytes coexpressing EAAT3 with mTOR was similar in the presence and absence of rapamycin (100 nM). In conclusion, mTOR is a novel powerful regulator of EAAT3 and may thus contribute to protection against neuroexcitotoxicity.     

High-affinity glutamate transporter GLAST/EAAT1 regulates cell surface expression of glutamine/neutral amino acid transporter ASCT2 in human fetal astrocytes

Neutral amino acid transporter ASCT2, together with high-affinity glutamate transporters, belongs to the SLC1 gene family of Na(+)-dependent solute carriers and is one of the major transporters of glutamine in cultured astrocytes. Besides glutamine and other high-affinity substrates--alanine, serine, cysteine or threonine, ASCT2 can also translocate protonated glutamate. The present study elucidated substrate-dependent trafficking of ASCT2 in differentiated primary cultures of human fetal astrocytes. The differentiation induced by 8-bromo-cAMP caused dramatic up-regulation of two co-localized and functionally linked astroglial proteins--glutamate transporter GLAST, that is the only high-affinity router of glutamate into cultured astrocytes, and glutamine synthetase (GS), a cytosolic enzyme that converts at least a part of the arriving glutamate into glutamine. In order to distinguish individual intracellular effects of these two substrates on ASCT2, in some cultures glutamine synthetase was effectively knocked down using siRNA silencing technique. In control conditions, regardless of GS levels, almost the entire ASCT2 immunoreactivity was restricted to the cytosol. Both glutamine and alanine, though to different extents, induced partial redistribution of ASCT2 from the cytosolic compartment to the plasma membrane. However, in cultures with high GS expression, micromolar concentrations of glutamate exhibited more pronounced effect on ASCT2 trafficking than the preferred substrates of this carrier. In contrast, glutamate had no effect on ASCT2 distribution in cultures devoid of GS. D-Aspartate, a metabolically inert substrate effectively transported by GLAST, had no effect in any cell culture utilized. It seems that intracellular glutamine produced by GS from glutamate that, in turn, is supplied by GLAST, is a more potent inducer of ASCT2 trafficking to the cell surface than the ASCT2-mediated translocation of extracellular substrates. At lower pH values (6.2-6.7), the cell surface pool of ASCT2 was significantly larger than at physiological pH. In addition, high concentrations of glutamate, independently from GLAST or glutamate receptor activation, induced further arrival of ASCT2 to the plasma membrane. The pH-dependent functional activation of ASCT2 and the ASCT2-mediated glutamate uptake may play important roles during ischemic acidosis or synaptic activity-induced local acidification.     

Cysteine mutagenesis reveals alternate proximity between transmembrane domain 2 and hairpin loop 1 of the glutamate transporter EAAT1

Excitatory amino acid transporter 1 (EAAT1) plays an important role in restricting the neurotoxicity of glutamate. Previous structure–function studies have provided evidence that reentrant helical hairpin loop (HP) 1 has predominant function during the transport cycle. The proposed internal gate HP1 is packed against transmembrane domain (TM) 2 and TM5 in its closed state, and two residues located in TM2 and HP2 of EAAT1 are in close proximity. However, the spatial relationship between TM2 and HP1 during the transport cycle remains unknown. In this study, we used chemical cross-linking of introduced cysteine pair (V96C and S366C) in a cysteine-less version of EAAT1 to assess the proximity of TM2 and HP1. Here, we show that inhibition of transport by copper(II)(1,10-phenanthroline)₃ (CuPh) and cadmium ion (Cd²⁺) were observed in the V96C/S366C mutant. Glutamate or potassium significantly protected against the inhibition of transport activity of V96C/S366C by CuPh, while TBOA potentiated the inhibition of transport activity of V96C/S366C by CuPh. We also checked the kinetic parameters of V96C/S366C treated with or without CuPh in the presence of NaCl, NaCl + l-glutamate, NaCl + TBOA, and KCl, respectively. The sensitivity of V96C and S366C to membrane-impermeable sulfhydryl reagent MTSET [(2-trimethylammonium) methanethiosulfonate] was attenuated by glutamate or potassium. TBOA had no effect on the sensitivity of V96C and S366C to MTSET. These data suggest that the spatial relationship between Val-96 of TM2 and Ser-366 of HP1 is altered in the transport cycle.     

Structure-activity relationship study of pyridazine derivatives as glutamate transporter EAAT2 activators

Excitatory amino acid transporter 2 (EAAT2) is the major glutamate transporter and functions to remove glutamate from synapses. A thiopyridazine derivative has been found to increase EAAT2 protein levels in astrocytes. A structure-activity relationship study revealed that several components of the molecule were required for activity, such as the thioether and pyridazine. Modification of the benzylthioether resulted in several derivatives (7-13, 7-15 and 7-17) that enhanced EAAT2 levels by >6-fold at concentrations < 5 μM after 24h. In addition, one of the derivatives (7-22) enhanced EAAT2 levels 3.5-3.9-fold after 24h with an EC(50) of 0.5 μM.     

Alternate splicing and expression of the glutamate transporter EAAT5 in the rat retina

Excitatory amino acid transporter 5 (EAAT5) is an unusual glutamate transporter that is expressed in the retina, where it is localised to two populations of glutamatergic neurons, namely the bipolar neurons and photoreceptors. EAAT5 exhibits two distinct properties, acting both as a slow glutamate transporter and as a glutamate-gated inhibitory receptor. The latter property is attributable to a co-associated chloride conductance. EAAT5 has previously been thought to exist only as a full-length form. We now demonstrate by PCR cloning and sequencing, the presence of five novel splice variant forms of EAAT5 which skip either partial or complete exons in the rat retina. Furthermore, we demonstrate that each of these variants is expressed at the protein level as assessed by Western blotting using splice-specific antibodies that we have generated. We conclude that EAAT5 exists in multiple spliced forms, and propose, based upon retention or absence of key structural features, that these variant forms may potentially exhibit distinct properties relative to the originally described form of EAAT5.     

Water and urea permeation pathways of the human excitatory amino acid transporter EAAT1

Glutamate transport is coupled to the co-transport of 3 Na(+) and 1 H(+) followed by the counter-transport of 1 K(+). In addition, glutamate and Na(+) binding to glutamate transporters generates an uncoupled anion conductance. The human glial glutamate transporter EAAT1 (excitatory amino acid transporter 1) also allows significant passive and active water transport, which suggests that water permeation through glutamate transporters may play an important role in glial cell homoeostasis. Urea also permeates EAAT1 and has been used to characterize the permeation properties of the transporter. We have previously identified a series of mutations that differentially affect either the glutamate transport process or the substrate-activated channel function of EAAT1. The water and urea permeation properties of wild-type EAAT1 and two mutant transporters were measured to identify which permeation pathway facilitates the movement of these molecules. We demonstrate that there is a significant rate of L-glutamate-stimulated passive and active water transport. Both the passive and active L-glutamate-stimulated water transport is most closely associated with the glutamate transport process. In contrast, L-glutamate-stimulated [(14)C]urea permeation is associated with the anion channel of the transporter. However, there is also likely to be a transporter-specific, but glutamate independent, flux of water via the anion channel.     

Stimulation of the EAAT4 glutamate transporter by SGK protein kinase isoforms and PKB

The serum and glucocorticoid inducible kinase (SGK) 1 is expressed in brain tissue and upregulated by ischemia, neuronal excitation, and dehydration. The present study has been performed to elucidate the expression of SGK1 in cerebellar Purkinje cells and to explore whether it influences the colocalized glutamate transporter EAAT4. Intense SGK1 staining was observed in Purkinje cells following 48h of water deprivation. The kinase activates glutamate induced current (I(GLU)) in Xenopus oocytes heterologously expressing EAAT4, an effect mimicked by its isoforms SGK2, 3 and PKB. I(GLU) was decreased by the ubiquitin ligase Nedd4-2, an effect partially but not completely reversed by additional coexpression of the SGK kinase isoforms or PKB. According to immunohistochemistry EAAT4 protein abundance in the cell membrane was enhanced by SGK1 and decreased by Nedd4-2. In conclusion, SGK1 expression is upregulated by ischemia, excitation, and dehydration in cerebellar Purkinje cells. The upregulation of SGK1 may serve to stimulate EAAT4 and thus to reduce neuroexcitotoxicity.