Structures of metabotropic GABAB receptor.

Stimulation of the metabotropic GABAB receptor by γ-aminobutyric acid (GABA) results in prolonged inhibition of neurotransmission, which is central to brain physiology1. GABAB belongs to family C of the G-protein-coupled receptors, which operate as dimers to transform synaptic neurotransmitter signals into a cellular response through the binding and activation of heterotrimeric G proteins2,3. However, GABAB is unique in its function as an obligate heterodimer in which agonist binding and G-protein activation take place on distinct subunits4,5. Here we present cryo-electron microscopy structures of heterodimeric and homodimeric full-length GABAB receptors. Complemented by cellular signalling assays and atomistic simulations, these structures reveal that extracellular loop 2 (ECL2) of GABAB has an essential role in relaying structural transitions by ordering the linker that connects the extracellular ligand-binding domain to the transmembrane region. Furthermore, the ECL2 of each of the subunits of GABAB caps and interacts with the hydrophilic head of a phospholipid that occupies the extracellular half of the transmembrane domain, thereby providing a potentially crucial link between ligand binding and the receptor core that engages G proteins. These results provide a starting framework through which to decipher the mechanistic modes of signal transduction mediated by GABAB dimers, and have important implications for rational drug design that targets these receptors.

Exploring the Binding Mechanism of GABAB Receptor Agonists and Antagonists through in Silico Simulations.

GABAB is a G protein-coupled receptor that functions as a constitutive heterodimer composed of the GABAB1a/b and GABAB2 subunits. It mediates slow and prolonged inhibitory neurotransmission in the nervous system, representing an attractive target for the treatment of various disorders. However, the molecular mechanism of the GABAB receptor is not thoroughly understood. Therefore, a better description of the binding of existing agonists and antagonists to this receptor is crucial to improve our knowledge about G protein-coupled receptor structure as well as for helping the development of new potent and more selective therapeutic agents. In this work, we used the recent X-ray cocrystallization data of agonists (GABA and baclofen) and antagonists (2-hydroxysaclofen, SCH50911, and CGP54626) bound to the GABAB orthosteric site together with quantum biochemistry and the molecular fractionation with conjugate caps (MFCC) scheme to describe the individual contribution of each amino acid residue involved in the GABAB-ligand interaction, pointing out differences and similarities among the compounds. Our quantum biochemical computational results show that the total binding energy of the ligands to the GABAB ligand pocket, with radius varying from 2.0 to 9.0 Å, is well-correlated with the experimental binding affinity. In addition, we found that the binding site is very similar for agonists or antagonists, showing small differences in the importance of the most significant amino acids. Finally, we predict the energetic relevance of the regions of the five ligands as well as the influence of each protein lobe on GABAB-ligand binding. These results provide important new information on the binding mechanism of the GABAB receptor and should facilitate the development of new chemicals targeting this receptor.

Interaction of GABAA and GABAB antagonists after status epilepticus in immature rats.

Among neurotransmitter systems affected by status epilepticus (SE) in adult rats are both GABAergic systems. To analyze possible changes of GABAA and GABAB systems in developing rats lithium-pilocarpine SE was induced at postnatal day 12 (P12). Seizures were elicited by a GABAA antagonist pentylenetetrazol (PTZ) 3, 6, 9, and 13 days after SE (i.e., in P15, P18, P21, and P25 rats), and their possible potentiation by a GABAB receptor antagonist CGP46381 was studied. Pilocarpine was replaced by saline in control animals (lithium-paraldehyde [LiPAR]). Pentylenetetrazol in a dose of 50 mg/kg s.c. elicited generalized seizures in nearly all 15-day-old naive rats and in 40% of 18-day-old ones but not in older animals. After SE, PTZ no longer elicited seizures in these two younger groups, i.e., sensitivity of GABAA system was diminished. The GABAB antagonist exhibited proconvulsant effect in P15 and P18 SE as well as LiPAR rats returning the incidence of PTZ-induced seizures to values of control animals. A decrease in the incidence of minimal clonic seizures was seen in P21 LiPAR animals; these seizures in the oldest group were not affected. Change of the effect from proconvulsant to anticonvulsant (or at least to no action) took place before postnatal day 21. Both SE and LiPAR animals exhibited similar changes but their intensity differed, effects in LiPAR controls were usually more expressed than in SE rats.

FRET-Based Sensors Unravel Activation and Allosteric Modulation of the GABAB Receptor.

The main inhibitory neurotransmitter, γ-aminobutyric acid (GABA), modulates many synapses by activating the G protein-coupled receptor GABAB, which is a target for various therapeutic applications. It is an obligatory heterodimer made of GB1 and GB2 that can be regulated by positive allosteric modulators (PAMs). The molecular mechanism of activation of the GABAB receptor remains poorly understood. Here, we have developed FRET-based conformational GABAB sensors compatible with high-throughput screening. We identified conformational changes occurring within the extracellular and transmembrane domains upon receptor activation, which are smaller than those observed in the related metabotropic glutamate receptors. These sensors also allow discrimination between agonists of different efficacies and between PAMs that have different modes of action, which has not always been possible using conventional functional assays. Our study brings important new information on the activation mechanism of the GABAB receptor and should facilitate the screening and identification of new chemicals targeting this receptor.