Claudia Alleva scite author profile

Excitatory amino acid transporters (EAATs) harness [Na+], [K+], and [H+] gradients for fast and efficient glutamate removal from the synaptic cleft. Since each glutamate is cotransported with three Na+ ions, [Na+] gradients are the predominant driving force for glutamate uptake. We combined all-atom molecular dynamics simulations, fluorescence spectroscopy, and x-ray crystallography to study Na+:substrate coupling in the EAAT homolog GltPh. A lipidic cubic phase x-ray crystal structure of wild-type, Na+-only bound GltPh at 2.5-Å resolution revealed the fully open, outward-facing state primed for subsequent substrate binding. Simulations and kinetic experiments established that only the binding of two Na+ ions to the Na1 and Na3 sites ensures complete HP2 gate opening via a conformational selection-like mechanism and enables high-affinity substrate binding via electrostatic attraction. The combination of Na+-stabilized gate opening and electrostatic coupling of aspartate to Na+ binding provides a constant Na+:substrate transport stoichiometry over a broad range of neurotransmitter concentrations.

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Allosteric gate modulation confers K ⁺ coupling in glutamate transporters

Kortzak

Alleva

Weyand

et al. 2019

The EMBO Journal

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Excitatory amino acid transporters (EAATs) mediate glial and neuronal glutamate uptake to terminate synaptic transmission and to ensure low resting glutamate concentrations. Effective glutamate uptake is achieved by cotransport with 3 Na+ and 1 H+, in exchange with 1 K+. The underlying principles of this complex transport stoichiometry remain poorly understood. We use molecular dynamics simulations and electrophysiological experiments to elucidate how mammalian EAATs harness K+ gradients, unlike their K+‐independent prokaryotic homologues. Glutamate transport is achieved via elevator‐like translocation of the transport domain. In EAATs, glutamate‐free re‐translocation is prevented by an external gate remaining open until K+ binding closes and locks the gate. Prokaryotic GltPh contains the same K+‐binding site, but the gate can close without K+. Our study provides a comprehensive description of K+‐dependent glutamate transport and reveals a hitherto unknown allosteric coupling mechanism that permits adaptions of the transport stoichiometry without affecting ion or substrate binding.

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Gating Charge Calculations by Computational Electrophysiology Simulations

Machtens

Briones

Alleva

et al. 2017

Biophysical Journal

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Electrical cell signaling requires adjustment of ion channel, receptor, or transporter function in response to changes in membrane potential. For the majority of such membrane proteins, the molecular details of voltage sensing remain insufficiently understood. Here, we present a molecular dynamics simulation-based method to determine the underlying charge movement across the membrane-the gating charge-by measuring electrical capacitor properties of membrane-embedded proteins. We illustrate the approach by calculating the charge transfer upon membrane insertion of the HIV gp41 fusion peptide, and validate the method on two prototypical voltage-dependent proteins, the Kv1.2 K channel and the voltage sensor of the Ciona intestinalis voltage-sensitive phosphatase, against experimental data. We then use the gating charge analysis to study how the T1 domain modifies voltage sensing in Kv1.2 channels and to investigate the voltage dependence of the initial binding of two Na ions in Na-coupled glutamate transporters. Our simulation approach quantifies various mechanisms of voltage sensing, enables direct comparison with experiments, and supports mechanistic interpretation of voltage sensitivity by fractional amino acid contributions.

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Molecular Basis of Coupled Transport and Anion Conduction in Excitatory Amino Acid Transporters

et al. 2021

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Glutamate is the major excitatory neurotransmitter in the mammalian central nervous system. After its release from presynaptic nerve terminals, glutamate is quickly removed from the synaptic cleft by excitatory amino acid transporters (EAATs) 1–5, a subfamily of glutamate transporters. The five proteins utilize a complex transport stoichiometry that couples glutamate transport to the symport of three Na+ ions and one H+ in exchange with one K+ to accumulate glutamate against up to 106-fold concentration gradients. They are also anion-selective channels that open and close during transitions along the glutamate transport cycle. EAATs belong to a larger family of secondary-active transporters, the SLC1 family, which also includes purely Na+- or H+-coupled prokaryotic transporters and Na+-dependent neutral amino acid exchangers. In recent years, molecular cloning, heterologous expression, cellular electrophysiology, fluorescence spectroscopy, structural approaches, and molecular simulations have uncovered the molecular mechanisms of coupled transport, substrate selectivity, and anion conduction in EAAT glutamate transporters. Here we review recent findings on EAAT transport mechanisms, with special emphasis on the highly conserved hairpin 2 gate, which has emerged as the central processing unit in many of these functions.

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Heavy-metal modulation of the human intercellular adhesion molecule (ICAM-1) gene expression

Martinotti

Toniato

Colagrande

et al. 1995

Biochimica et Biophysica Acta (BBA) - Gene Structure and Expres

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Claudia Alleva

Na ⁺ -dependent gate dynamics and electrostatic attraction ensure substrate coupling in glutamate transporters

Allosteric gate modulation confers K ⁺ coupling in glutamate transporters

Gating Charge Calculations by Computational Electrophysiology Simulations

Molecular Basis of Coupled Transport and Anion Conduction in Excitatory Amino Acid Transporters

Heavy-metal modulation of the human intercellular adhesion molecule (ICAM-1) gene expression

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Claudia Alleva

Na + -dependent gate dynamics and electrostatic attraction ensure substrate coupling in glutamate transporters

Allosteric gate modulation confers K + coupling in glutamate transporters

Gating Charge Calculations by Computational Electrophysiology Simulations

Molecular Basis of Coupled Transport and Anion Conduction in Excitatory Amino Acid Transporters

Heavy-metal modulation of the human intercellular adhesion molecule (ICAM-1) gene expression

Contact Info

Product

Resources

About

Na ⁺ -dependent gate dynamics and electrostatic attraction ensure substrate coupling in glutamate transporters

Allosteric gate modulation confers K ⁺ coupling in glutamate transporters