Sun W et al. (2011), Specificity and actions of an arylaspartate inh...

XB-ART-43815

PLoS One 2011 Jan 01;68:e23765. doi: 10.1371/journal.pone.0023765.

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Specificity and actions of an arylaspartate inhibitor of glutamate transport at the Schaffer collateral-CA1 pyramidal cell synapse.

Sun W , Hoffman KM , Holley DC , Kavanaugh MP .

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In this study we characterized the pharmacological selectivity and physiological actions of a new arylaspartate glutamate transporter blocker, L-threo-ß-benzylaspartate (L-TBA). At concentrations up to 100 µM, L-TBA did not act as an AMPA receptor (AMPAR) or NMDA receptor (NMDAR) agonist or antagonist when applied to outside-out patches from mouse hippocampal CA1 pyramidal neurons. L-TBA had no effect on the amplitude of field excitatory postsynaptic potentials (fEPSPs) recorded at the Schaffer collateral-CA1 pyramidal cell synapse. Excitatory postsynaptic currents (EPSCs) in CA1 pyramidal neurons were unaffected by L-TBA in the presence of physiological extracellular Mg(2+) concentrations, but in Mg(2+)-free solution, EPSCs were significantly prolonged as a consequence of increased NMDAR activity. Although L-TBA exhibited approximately four-fold selectivity for neuronal EAAT3 over glial EAAT1/EAAT2 transporter subtypes expressed in Xenopus oocytes, the L-TBA concentration-dependence of the EPSC charge transfer increase in the absence of Mg(2+) was the same in hippocampal slices from EAAT3 +/+ and EAAT3 -/- mice, suggesting that TBA effects were primarily due to block of glial transporters. Consistent with this, L-TBA blocked synaptically evoked transporter currents in CA1 astrocytes with a potency in accord with its block of heterologously expressed glial transporters. Extracellular recording in the presence of physiological Mg(2+) revealed that L-TBA prolonged fEPSPs in a frequency-dependent manner by selectively increasing the NMDAR-mediated component of the fEPSP during short bursts of activity. The data indicate that glial glutamate transporters play a dominant role in limiting extrasynaptic transmitter diffusion and binding to NMDARs. Furthermore, NMDAR signaling is primarily limited by voltage-dependent Mg(2+) block during low-frequency activity, while the relative contribution of transport increases during short bursts of higher frequency signaling.

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Species referenced: Xenopus
Genes referenced: slc1a1 slc1a2 slc1a3

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	Figure 1. Interaction of L-TBA with EAATs.(A) Docking of L-TBA (green) and L-TBOA (gray) in EAAT3 model showing overlap of functional groups interacting with R447 and D444, with benzyl groups oriented toward extracellular loop HP2 as described in [14]. (B) Surface depiction of the transporter binding site (hydrophobic regions blue) showing L-TBA and alternate docking orientation of L-TBOA with benzyl ring aligned in alternate hydrophobic pocket.
	Figure 2. Effects of L-TBA on native and recombinant transporters.(A) Representative recording from voltage-clamped Xenopus oocyte expressing astrocyte transporter subtype EAAT2. 100 ÂµM L-TBA partially blocks equimolar L-Glu uptake current mediated by EAAT2. (B) Summary of L-TBA concentration-dependence of block of 100 ÂµM L-Glu currents in oocytes expressing EAAT1-3, showing approximately four-fold selectivity for EAAT3 by least-squares minimized fits to mean data generating IC50 values of 56, 52, and 13 ÂµM, respectively. (C) Effect of 30 ÂµM L-TBA on synaptically activated transport current (STC) in hippocampal CA1 astrocyte. Currents in the presence or absence of L-TBA were evoked by stimulation in stratum radiatum in the continuous presence of ionotropic receptor antagonists (see methods). 30 ÂµM L-TBA blocked 66.7Â±10.4 of the peak STC (nâ=â4).
	Figure 3. Representative recordings from outside-out patches excised from CA1 pyramidal neurons illustrating AMPAR and NMDAR responses to rapid application of 100 ÂµM L-glutamate and/or 100 ÂµM L-TBA for durations indicated by solution exchange traces above.Responses at â60 mV showing lack of agonist or antagonist actions of L-TBA on AMPARs (A; with 1.2 mM Mg2+) and NMDARs (B; with 0 mM Mg2+/20 ÂµM glycine/20 ÂµM CNQX). Scale bars are 50/200 ms and 50/100 pA for AMPAR/NMDAR responses respectively. (C) Summary of mean effects of 100 ÂµM L-TBA on 100 ÂµM L-Glu AMPAR and NMDAR responses.
	Figure 4. Actions of L-TBA (30 ÂµM) on postsynaptic responses at the CA1 Schaffer collateral-pyramidal neuron synapse of EAAT3 +/+ (A) and EAAT3 â/â (B) mice.Representative whole cell recordings (â60 mV) showing effect of L-TBA on EPSCs evoked by stimulation in stratum radiatum in the presence (A1, B1) and absence (A2, B2) of physiological extracellular Mg2+ (1.2 mM). (C) Summary of data showing EPSC charge transfer increase in slices from EAAT3 (+/+) and (â/â) mice by 30 ÂµM L-TBA in the absence and presence of Mg2+ (nâ=â5â7 slices; p<0.05). Data normalized to the charge transfer in slices from EAAT3 (+/+) mice. (D) Summary data showing no significant difference in L-TBA concentration-dependence of EPSC charge transfer increase (normalized to control) for EAAT3 +/+ (open squares) and EAAT3 â/â (filled squares) (nâ=â4).
	Figure 5. Actions of L-TBA on field responses at the CA1 Schaffer collateral-pyramidal neuron synapse.(A) Representative field EPSPs elicited in response to three stimuli delivered at 20 Hz in stratum radiatum. 30 ÂµM L-TBA (black trace) prolonged fEPSPs relative to control (gray trace) in an activity-dependent manner (pâ=â0.02). The TBA prolongation was inhibited by co-application of 50 ÂµM DL-APV (2nd black trace). (B) Summary of effects on fEPSP time-integrals elicited by 1, 2 and 3 stimuli normalized to corresponding fEPSPs in control ACSF (*p<.05 paired t-test; nâ=â9 slices for one and two stimuli, nâ=â5 slices for three stimuli).

References [+] :

Arnth-Jensen, Cooperation between independent hippocampal synapses is controlled by glutamate uptake. 2002, Pubmed

Arnth-Jensen, Cooperation between independent hippocampal synapses is controlled by glutamate uptake. 2002, Pubmed
Asztely, Extrasynaptic glutamate spillover in the hippocampus: dependence on temperature and the role of active glutamate uptake. 1997, Pubmed
Bendahan, Arginine 447 plays a pivotal role in substrate interactions in a neuronal glutamate transporter. 2000, Pubmed , Xenbase
Bergles, Synaptic activation of glutamate transporters in hippocampal astrocytes. 1997, Pubmed
Boudker, Coupling substrate and ion binding to extracellular gate of a sodium-dependent aspartate transporter. 2007, Pubmed
Diamond, Neuronal glutamate transporters limit activation of NMDA receptors by neurotransmitter spillover on CA1 pyramidal cells. 2001, Pubmed
Esslinger, The substituted aspartate analogue L-beta-threo-benzyl-aspartate preferentially inhibits the neuronal excitatory amino acid transporter EAAT3. 2005, Pubmed , Xenbase
Furuta, Glutamate transporter protein subtypes are expressed differentially during rat CNS development. 1997, Pubmed
Holley, Interactions of alkali cations with glutamate transporters. 2009, Pubmed
Isaacson, The uptake inhibitor L-trans-PDC enhances responses to glutamate but fails to alter the kinetics of excitatory synaptic currents in the hippocampus. 1993, Pubmed
Lehre, The number of glutamate transporter subtype molecules at glutamatergic synapses: chemical and stereological quantification in young adult rat brain. 1998, Pubmed
Lozovaya, Enhancement of glutamate release uncovers spillover-mediated transmission by N-methyl-D-aspartate receptors in the rat hippocampus. 1999, Pubmed
Sarantis, Glutamate uptake from the synaptic cleft does not shape the decay of the non-NMDA component of the synaptic current. 1993, Pubmed
Scimemi, Neuronal transporters regulate glutamate clearance, NMDA receptor activation, and synaptic plasticity in the hippocampus. 2009, Pubmed
Shimamoto, DL-threo-beta-benzyloxyaspartate, a potent blocker of excitatory amino acid transporters. 1998, Pubmed , Xenbase
Shimamoto, Syntheses of optically pure beta-hydroxyaspartate derivatives as glutamate transporter blockers. 2000, Pubmed
Teichman, Aspartate-444 is essential for productive substrate interactions in a neuronal glutamate transporter. 2007, Pubmed , Xenbase
Tong, Block of glutamate transporters potentiates postsynaptic excitation. 1994, Pubmed
Tsukada, Effects of a novel glutamate transporter blocker, (2S, 3S)-3-[3-[4-(trifluoromethyl)benzoylamino]benzyloxy]aspartate (TFB-TBOA), on activities of hippocampal neurons. 2005, Pubmed
Tzingounis, Glutamate transporters: confining runaway excitation by shaping synaptic transmission. 2007, Pubmed
Yernool, Structure of a glutamate transporter homologue from Pyrococcus horikoshii. 2004, Pubmed