Single molecule FRET methodology for investigating glutamate receptors.

Single molecule Förster Resonance Energy Transfer (smFRET) allows us to measure variation in distances between donor and acceptor fluorophores attached to a protein, providing the conformational landscape of the protein with respect to this specific distance. smFRET can be performed on freely diffusing molecules or on tethered molecules. Here, we describe the tethered method used to study ionotropic glutamate receptors, which allows us to track the changes in FRET as a function of time, thus providing information on the conformations sampled and kinetics of conformational changes in the millisecond to second time scale. Strategies for attaching fluorophores to the proteins, methods for acquiring and analyzing the smFRET trajectories, and limitations are discussed.

Allosteric Changes in the NMDA Receptor Associated with Calcium-Dependent Inactivation.

N-methyl-D-aspartate (NMDA) receptors mediate synaptic excitatory signaling in the mammalian central nervous system by forming calcium-permeable transmembrane channels upon binding glutamate and coagonist glycine. Ca2+ influx through NMDA receptors leads to channel inactivation through a process mediated by resident calmodulin bound to the intracellular C-terminal segment of the GluN1 subunit of the receptor. Using single-molecule FRET investigations, we show that in the presence of calcium-calmodulin, the distance across the two GluN1 subunits at the entrance of the first transmembrane segment is shorter and the bilobed cleft of the glycine-binding domain in GluN1 is more closed when bound to glycine and glutamate relative to what is observed in the presence of barium-calmodulin. Consistent with these observations, the glycine deactivation rate is slower in the presence of calcium-calmodulin. Taken together, these results show that the binding of calcium-calmodulin to the C-terminus has long-range allosteric effects on the extracellular segments of the receptor that may contribute to the calcium-dependent inactivation.

Conformational spread and dynamics in allostery of NMDA receptors.

Allostery can be manifested as a combination of repression and activation in multidomain proteins allowing for fine tuning of regulatory mechanisms. Here we have used single molecule fluorescence resonance energy transfer (smFRET) and molecular dynamics simulations to study the mechanism of allostery underlying negative cooperativity between the two agonists glutamate and glycine in the NMDA receptor. These data show that binding of one agonist leads to conformational flexibility and an increase in conformational spread at the second agonist site. Mutational and cross-linking studies show that the dimer-dimer interface at the agonist-binding domain mediates the allostery underlying the negative cooperativity. smFRET on the transmembrane segments shows that they are tightly coupled in the unliganded and single agonist-bound form and only upon binding both agonists the transmembrane domain explores looser packing which would facilitate activation.