Abstract

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.

Highlights

  • Neutralizing a conserved aspartate between TM2 and TM3 affects gating of Excitatory amino acid transporters (EAATs) 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

  • M205C and A430C have already been used in earlier studies [23, 25], whereas V120C has not been reported to date

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Summary

Background

Neutralizing a conserved aspartate between TM2 and TM3 affects gating of EAAT 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. The data on fluorescence amplitudes and transport function can be described by a kinetic scheme in which only transitions within the uptake cycle are modified by the mutation, whereas the likelihood of anion channel opening was not changed in mutant transporters

EXPERIMENTAL PROCEDURES
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DISCUSSION

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