Analysis of the Functional Differentiation Sites in Vertebrate Neuronal Nicotinic Acetylcholine Receptor Subunits

The nicotinic acetylcholine receptors (nAChR) belong to a large family of ligand-gated ion channels and are involved in the mediation of fast synaptic transmission. Each receptor is made up of five subunits that arrange symmetrically around a central pore. Despite the similarity in their sequences and structures, the properties of these subunits vary significantly. Thus, identifying the function-related sites specific to each subunit is essential for understanding the characteristics of the subunits and the receptors assembled by them. In this study, we examined the sequence features of the nine neuronal nAChRs subunits from twelve representative vertebrate species. Analysis revealed that all the subunits were subject to strong purifying selection in evolution, and each was under a unique pattern of selection pressures. At the same time, the functional constraints were not uniform within each subunit, with different domains in the molecule being subject to different selection pressures. Via evolutionary analyses, we also detected potential positive selection events in the subunits or subunit clusters, and identified the sites might be associated with the function specificity of each subunit. Furthermore, positive selection at some domains might contributed to the diversity of subunit function; for example, the {beta}9 strand might be related to the agonist specificity of subunit in heteromeric receptor and {beta}4-{beta}5 linker could be involved in Ca2+ permeability. Subunits 7, 4 and {beta}2 subunits possess a strong adaptability in vertebrates. Our results highlighted the importance of tracking functional differentiation in protein sequence underlying functional properties of nAChRs. In summary, our work may provide clues on understanding the diversity and the function specificity of the nAChR subunits, as well as the receptors co-assembled by them.