NMDA receptors (NMDARs) are a major class of excitatory neurotransmitter receptors in the central nervous system. They form glutamate-gated ion channels highly permeable to calcium that mediate activity-dependent synaptic plasticity1. NMDAR dysfunction is implicated in multiple brain disorders, including stroke, chronic pain and schizophrenia2. NMDARs exist as multiple subtypes with distinct pharmacological and biophysical properties largely determined by the type of NR2 subunit (NR2A-NR2D) incorporated in the heteromeric NR1/NR2 complex1,3,4. A fundamental difference between NMDAR subtypes is their channel maximal open probability (Po), which spans a 50-fold range from ~0.5 for NR2A-containing receptors to ~0.01 for NR2C- and NR2D-containing receptors; NR2B-containing receptors having an intermediate value (~0.1)5–9. These differences in Po confer unique charge transfer capacities and signaling properties on each receptor subtype4,6,10,11. The molecular basis for this profound difference in activity between NMDAR subtypes is unknown. Here we demonstrate that the subunit-specific gating of NMDARs is controlled by the region formed by the NR2 N-terminal domain (NTD), an extracellular clamshell-like domain previously shown to bind allosteric inhibitors12–15, and the short linker connecting the NTD to the agonist-binding domain (ABD). Subtype specificity of NMDAR Po largely reflects differences in the spontaneous (ligand-independent) equilibrium between open-cleft and closed-cleft conformations of the NR2-NTD. This NTD-driven gating control also impacts pharmacological properties, by setting the sensitivity to the endogenous inhibitors zinc and protons. Our results provide a proof-of-concept for a drug-based bidirectional control of NMDAR activity using molecules acting either as NR2-NTD “closers” or “openers” promoting receptor inhibition or potentiation, respectively.
Levamisole-sensitive acetylcholine receptors (L-AChRs) are ligandgated ion channels that mediate excitatory neurotransmission at the neuromuscular junctions of nematodes. They constitute a major drug target for anthelminthic treatments because they can be activated by nematode-specific cholinergic agonists such as levamisole. Genetic screens conducted in Caenorhabditis elegans for resistance to levamisole toxicity identified genes that are indispensable for the biosynthesis of L-AChRs. These include 5 genes encoding distinct AChR subunits and 3 genes coding for ancillary proteins involved in assembly and trafficking of the receptors. Despite extensive analysis of L-AChRs in vivo, pharmacological and biophysical characterization of these receptors has been greatly hampered by the absence of a heterologous expression system. Using Xenopus laevis oocytes, we were able to reconstitute functional L-AChRs by coexpressing the 5 distinct receptor subunits and the 3 ancillary proteins. Strikingly, this system recapitulates the genetic requirements for receptor expression in vivo because omission of any of these 8 genes dramatically impairs L-AChR expression. We demonstrate that 3 ␣-and 2 non-␣-subunits assemble into the same receptor. Pharmacological analysis reveals that the prototypical cholinergic agonist nicotine is unable to activate L-AChRs but rather acts as a potent allosteric inhibitor. These results emphasize the role of ancillary proteins for efficient expression of recombinant neurotransmitter receptors and open the way for in vitro screening of novel anthelminthic agents.anthelminthic drug ͉ recombinant receptor expression
γ-aminobutyric acid receptors (GABAARs) are vital for controlling excitability in the brain. This is emphasized by the numerous neuropsychiatric disorders that result following receptor dysfunction. A critical component of most native GABAARs is the α subunit. Its transmembrane domain is the target for many modulators, including endogenous brain neurosteroids that impact on anxiety, stress and depression, and for therapeutic drugs such as general anaesthetics. To understand the basis for modulating GABAAR function, high-resolution structures are required. Here we present the first atomic structures of a GABAAR chimera at 2.8Å resolution, including those bound with potentiating and inhibitory neurosteroids. These define new allosteric binding sites for these modulators that are associated with the α-subunit transmembrane domain. Our findings will enable neurosteroids to be exploited for therapeutic drug design to regulate GABAARs in neurological disorders.
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