Abstract
In response to brief glutamate exposure, NMDA receptors produce excitatory currents that have sub-maximal amplitudes and characteristically slow kinetics. The activation sequence starts when glutamate binds to residues located on the upper lobe of extracellularly located ligand-binding domains (LBDs) and then contacts lower lobe residues to bridge the cleft between the two hinged lobes. This event stabilizes a narrow-cleft LBD conformation and may facilitate subsequent inter-lobe contacts that further stabilize the closed cleft. Agonist efficacy has been traced to the degree of agonist-induced cleft-closure and may also depend on the stability of the closed-cleft conformation. To investigate how cross-cleft contacts contribute to the amplitude and kinetics of NMDA receptor response, we examined the activation reaction of GluN1/GluN2A receptors that had single-residue substitutions at the interface between LBD lobes. We found that side-chain truncations at residues of putative contact between lobes increased glutamate efficacy through independent additive mechanisms in GluN1 and GluN2A subunits. In contrast, removing side-chain charge with isosteric substitutions at the same sites decreased glutamate efficacy. These results support the view that in GluN1/GluN2A receptors’ natural interactions between residues on opposing sides of the ligand-binding cleft encode the stability of the glutamate-bound closed-cleft conformations and limit the degree of cleft closure, thus contributing to the sub-maximal response and emblematically slow NMDA receptor deactivation after brief stimulation.
Highlights
Glutamate-activated channels sensitive to the synthetic agonists AMPA, kainate, or NMDA mediate almost all fast excitatory transmission between central neurons
We propose that specific interactions across the ligandbinding domains (LBDs) clefts of N1 and N2A subunits control the degree of cleft closure and/or the stability of the closed-cleft conformation, and each of these effects have distinct contributions to the observed glutamateelicited NMDA receptor response
Similar studies in NMDA receptors showed that substitutions in the cleft alter the receptor’s apparent affinity for glutamate, but it remains unclear whether these residues contact each other in full-length receptors, and whether they affect the shape of the NMDA receptor response [25,26,27]
Summary
Glutamate-activated channels sensitive to the synthetic agonists AMPA, kainate, or NMDA mediate almost all fast excitatory transmission between central neurons. NMDA receptors have several characteristic features that make them uniquely suited to the functions they serve in synaptic physiology: high calcium permeability, voltagedependent block by magnesium ions, and distinctively slow deactivation kinetics (reviewed in 1). High-resolution structural data for a large number of ligand-LBD complexes have established that agonists form multidentate contacts with residues located on the two opposing lobes and subsequently facilitate direct cross-cleft interactions between D1 and D2 residues [15]. Together these interactions help to stabilize a subset of closed-cleft conformations that is characteristic for each ligand-LBD complex [16,17]
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