Distinct evolutionary trajectories of neuronal and hair cell nicotinic acetylcholine receptors

Abstract

ABSTRACTThe expansion and pruning of ion channel families has played a crucial role in the evolution of nervous systems. Remarkably, with a highly conserved vertebrate complement, nicotinic acetylcholine receptors (nAChRs) are unique among ligand-gated ion channels in that members of the family have distinct roles in synaptic transmission in non-overlapping domains, either in the nervous system, the inner ear hair cells or the neuromuscular junction. Here, we performed a comprehensive analysis of vertebrate nAChRs sequences, single cell expression patterns and comparative functional properties of receptors from three representative tetrapod species. We show that hair cell nAChRs underwent a distinct evolutionary trajectory to that of neuronal receptors. These were most likely shaped by different co-expression patterns and co-assembly rules of component subunits. Thus, neuronal nAChRs showed high degree of coding sequence conservation, coupled to greater co-expression variance and conservation of functional properties across tetrapod clades. In contrast, hair cell α9α10 nAChRs exhibited greater sequence divergence, narrow co-expression pattern and great variability of functional properties across species. These results point to differential substrates for random change within the family of gene paralogs that relate to the segregated roles of nAChRs in synaptic transmission.Significance statementOur work exploits several peculiarities of the family of vertebrate nicotinic acetylcholine receptors (nAChRs) to explore the evolutionary trajectories of a ligand-gated ion channel family. By performing a comprehensive comparative analysis of nAChR subunits coding sequences, single cell expression patterns and functional properties we found a contrasting evolutionary history between nAChRs with widespread expression in the nervous system compared to those with isolated expression in the inner ear. Evolutionary changes were focused on differences in co-expression and co-assembly patterns for the former and coding sequences in the latter. This multidisciplinary approach provides further insight into the evolutionary processes that shaped the nervous and sensory systems of extant animals.