A single main-chain hydrogen bond required to keep GABA_Areceptors closed

GABA_Areceptors are the primary inhibitory neurotransmitter receptors throughout the central nervous system. Despite significant progress understanding their three-dimensional structure, a critical gap remains in determining the molecular basis for channel gating. We recently identified M2-M3 linker mutations that suggest linker flexibility has asymmetric subunit-specific correlations with channel opening. Here we use non-canonical amino acids (ncAAs) to investigate the role of main-chain H-hydrogen bonds (H-bonds) that may stabilize the M2-M3 linkers. We show that a single main-chain H-bond within the β2 subunit M2-M3 linker inhibits pore opening and is required to keep the unliganded channel closed. Furthermore, breaking this H-bond during channel opening accounts for approximately one third of the activation energy derived from GABA binding. In contrast, the analogous H-bond in the α1 subunit has no effect on gating. Our observations suggest that channel opening involves state-dependent breakage/disruption of a specific main-chain H-bond within the β2 subunit M2-M3 linker.