Abstract
Excitatory amino acid transporters (EAAT) play a key role in glutamatergic synaptic communication. Driven by transmembrane cation gradients, these transporters catalyze the reuptake of glutamate from the synaptic cleft once this neurotransmitter has been utilized for signaling. Two decades ago, pioneering studies in the Kanner lab identified a conserved methionine within the transmembrane domain as key for substrate turnover rate and specificity; later structural work, particularly for the prokaryotic homologs GltPh and GltTk, revealed that this methionine is involved in the coordination of one of the three Na+ ions that are co-transported with the substrate. Albeit extremely atypical, the existence of this interaction is consistent with biophysical analyses of GltPh showing that mutations of this methionine diminish the binding cooperativity between substrates and Na+. It has been unclear, however, whether this intriguing methionine influences the thermodynamics of the transport reaction, i.e., its substrate:ion stoichiometry, or whether it simply fosters a specific kinetics in the binding reaction, which, while influential for the turnover rate, do not fundamentally explain the ion-coupling mechanism of this class of transporters. Here, studies of GltTk using experimental and computational methods independently arrive at the conclusion that the latter hypothesis is the most plausible, and lay the groundwork for future efforts to uncover the underlying mechanism.
Highlights
Glutamatergic synapses are the primary excitatory synapses in the brain and are thought to be essential for learning and memory
Reuptake of glutamate is key to maintaining healthy levels, a task that falls largely to membrane transporters belonging to the SLC1 family, known as excitatory amino acid transporters (EAAT) in the transporter classification database (TCDB) family 2.A.23 [3, 4]
Examples of methionine or cysteine side chains interacting with a sodium ion in known structures were assessed by searching the Protein Data Bank (PDB) as of 2020-1014
Summary
Glutamatergic synapses are the primary excitatory synapses in the brain and are thought to be essential for learning and memory. In this form of chemical signaling, glutamate is released by the presynaptic nerve terminal, activating receptor proteins on the surface of the post-synaptic neuron. Structures of prokaryotic SLC1 homologues, including G ltPh and G ltTk, from Pyrococcus horikoshii and Thermococcus kodakarensis, respectively [5,6,7], and of a thermally-stabilized mutant of EAAT1 (SLC1A1 or GLAST) [8], reveal a trimeric assembly, where each protomer contains eight transmembrane (TM) segments and two helical hairpins, HP1 and HP2. The three protomers interact through their so-called trimerization domains
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