Adrienne P. Loh

Dynamics of the S1S2 Glutamate Binding Domain of GluR2 Measured Using 19F NMR Spectroscopy

Ionotropic glutamate receptors mediate the majority of vertebrate excitatory synaptic transmission. Although the structure of the GluR2 binding domain (S1S2) is well known (agonist binding site between two lobes), little is known about the time scales of conformational transitions or the relationship between dynamics and function. 19F NMR (19F-labeled tryptophan) spectroscopy was used to monitor motions in the S1S2 domain bound to ligands with varying efficacy and in the apo state. One tryptophan (Trp-671) undergoes chemical exchange in some but not all agonists, consistent with μs-ms motion. The dynamics can be correlated to ligand affinity, and a likely source of the motion is a peptide bond capable of transiently forming hydrogen bonds across the lobe interface. Another tryptophan (Trp-767) appears to monitor motions of the relative positions of the lobes and suggests that the relative orientation in the apo- and antagonist-bound forms can exchange between at least two conformations on the ms time scale.

Structure of Glutamate Receptors

Glutamate receptors mediate a vast array of processes in plants, animals and bacteria. In particular, the ionotropic glutamate receptors (iGluRs) are the most abundant excitatory neurotransmitter receptors in the mammalian central nervous system. Because these proteins are constructed from distinct folding domains, most of which can be traced to bacterial precursors, the analyses of these important receptor proteins has been performed on a variety of levels ranging from atomic structure and dynamics to behavioral studies. This review will focus on the structure and dynamics of iGluRs, with particular emphasis on the role that the glutamate-binding domain (S1S2) plays in receptor function.

Thermodynamics and mechanism of the interaction of willardiine partial agonists with a glutamate receptor: implications for drug development.

Understanding the thermodynamics of binding of a lead compound to a receptor can provide valuable information for drug design. The binding of compounds, particularly partial agonists, to subtypes of the α-amino-3-hydroxy-5-methyl-4-isoxazole-propionic acid (AMPA) receptor is, in some cases, driven by increases in entropy. Using a series of partial agonists based on the structure of the natural product, willardiine, we show that the charged state of the ligand determines the enthalpic contribution to binding. Willardiines have uracil rings with pKa values ranging from 5.5 to 10. The binding of the charged form is largely driven by enthalpy, while that of the uncharged form is largely driven by entropy. This is due at least in part to changes in the hydrogen bonding network within the binding site involving one water molecule. This work illustrates the importance of charge to the thermodynamics of binding of agonists and antagonists to AMPA receptors and provides clues for further drug discovery.