Abstract
Glutamatergic AMPA (α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid) and NMDA (N-methyl-D-aspartate) receptors are implicated in diverse functions ranging from synaptic plasticity to cell death. They are heterotetrameric proteins whose subunits are derived from multiple distinct gene families. The subunit composition of these receptors determines their permeability to monovalent and/or divalent cations, but it is not entirely clear how this selectivity arises in native and recombinantly-expressed receptor populations. By analyzing the sequence of amino acids lining the selectivity filters within the pore forming membrane helices (M2) of these subunits and by correlating subunit stoichiometry of these receptors with their ability to permeate Na+ and/or Ca2+, we propose here a mathematical model for predicting cation selectivity and permeability in these receptors. The model proposed is based on principles of charge attractivity and charge neutralization within the pore forming region of these receptors; it accurately predicts and reconciles experimental data across various platforms including Ca2+ permeability of GluA2-lacking AMPARs and ion selectivity within GluN3-containing di- and tri-heteromeric NMDARs. Additionally, the model provides insights into biophysical mechanisms regulating cation selectivity and permeability of these receptors and the role of various subunits in these processes.
Highlights
Cation selectivity and permeability are important attributes of AMPA and NMDA receptor function impacting a variety of Na+/Ca2+-dependent cellular processes in the brain
Higher selectivity likely facilitates increased permeability on account of the electrostatic repulsion of a monovalent cation by a divalent cation and the speedingup of divalent cation flow when the channel becomes multiply occupied (Sharma and Stevens, 1996). This taken together with the fact that unsolvated Na+ and Ca2+ ions are comparable in size (Shannon, 1976; inset, Figure 1), suggests that the increased permeability to Ca2+ and decreased permeability to Na+ in these receptor subtypes may arise from subunit-mediated cation selectivity
This work describes a model for cation selectivity and permeability in AMPA and NMDA receptors based on receptor subunit composition
Summary
Cation selectivity and permeability are important attributes of AMPA and NMDA receptor function impacting a variety of Na+/Ca2+-dependent cellular processes in the brain. While Ca2+ influx through NMDARs can bring about synaptic plasticity, the basis of learning and memory, or cell death from excitotoxicity (Collingridge, 1987; McBain and Mayer, 1994; Sheng et al, 1994; Cull-Candy et al, 2001), these receptors usually rely on Na+ influx through co-expressed AMPARs for the depolarization required to relieve them of their voltage dependent Mg2+ blockade for activation (Mayer et al, 1984) How do these receptors achieve this specificity for cations and what factors influence their permeability? This study sheds light on the organizing principles that govern subunit-dependent cation selectivity in these receptors
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