Abstract
The Cys loop family of ligand-gated ion channels mediate fast synaptic transmission for communication between neurons. They are allosteric proteins, in which binding of a neurotransmitter to its binding site in the extracellular amino-terminal domain triggers structural changes in distant transmembrane domains to open a channel for ion flow. Although the locations of binding site and channel gating machinery are well defined, the structural basis of the activation pathway coupling binding and channel opening remains to be determined. In this paper, by analyzing amino acid covariance in a multiple sequence alignment, we have identified an energetically interconnected network in the Cys loop family of ligand-gated ion channels. Statistical coupling and correlated mutational analyses along with clustering revealed a highly coupled cluster. Mapping the positions in the cluster onto a three-dimensional structural model demonstrated that these highly coupled positions form an interconnected network linking experimentally identified binding domains through the coupling region to the gating machinery. In addition, these highly coupled positions are also condensed in the transmembrane domains, which are a recent focus for the sites of action of many allosteric modulators. Thus, our results revealed a genetically interconnected network that potentially plays an important role in the allosteric activation and modulation of the Cys loop family of ligand-gated ion channels.
Highlights
Ligand-gated ion channels (LGICs)2 mediate fast synaptic transmission for communication between neurons
Static Energy—To calculate the coupling, we started by counting occurrences of amino acids at each position in the multiple sequence alignment (MSA)
The magnitude of the static energy represents the extent of deviation of the amino acid distribution at each site from the mean in the MSA and represents the extent of residue conservation at that site
Summary
Ligand-gated ion channels (LGICs) mediate fast synaptic transmission for communication between neurons. In this paper, using these two approaches with different scoring systems, we have identified a cluster of genetically covariant sites in the Cys loop receptors Mapping these positions onto the three-dimensional structural model of a nicotinic receptor subunit reveals that these positions are mainly clustered in functionally important domains, forming an interconnected allosteric network linking the agonist-binding pocket to the gating machinery via coupling domains. These highly coupled positions are clustered in transmembrane domains, the recent focus for the sites of action of many allosteric modulators.
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