Molecular Evolution and Functional Divergence of Trace Amine–Associated Receptors

Authors

Seong-il Eyun, University of Nebraska - LincolnFollow
Hideaki Moriyama, University of Nebraska-LincolnFollow
Federico G. Hoffmann, University of Nebraska-LincolnFollow
Etsuko N. Moriyama, University of Nebraska-LincolnFollow

Date of this Version

3-9-2016

Citation

Eyun S-i, Moriyama H, Hoffmann FG, Moriyama EN (2016) Molecular Evolution and Functional Divergence of Trace Amine–Associated Receptors. PLoS ONE 11(3): e0151023. doi:10.1371/ journal.pone.0151023

Comments

Copyright: © 2016 Eyun et al. This is an open access article distributed under the terms of the Creative Commons Attribution License.

Abstract

Trace amine-associated receptors (TAARs) are a member of the G-protein-coupled receptor superfamily and are known to be expressed in olfactory sensory neurons. A limited number of molecular evolutionary studies have been done for TAARs so far. To elucidate how lineage-specific evolution contributed to their functional divergence, we examined 30 metazoan genomes. In total, 493 TAAR gene candidates (including 84 pseudogenes) were identified from 26 vertebrate genomes. TAARs were not identified from non-vertebrate genomes. An ancestral-type TAAR-like gene appeared to have emerged in lamprey.We found four therian-specific TAAR subfamilies (one eutherian-specific and three metatherian- specific) in addition to previously known nine subfamilies. Many species-specific TAAR gene duplications and losses contributed to a large variation of TAAR gene numbers among mammals, ranging from 0 in dolphin to 26 in flying fox. TAARs are classified into two groups based on binding preferences for primary or tertiary amines as well as their sequence similarities. Primary amine-detecting TAARs (TAAR1-4) have emerged earlier, generally have single-copy orthologs (very few duplication or loss), and have evolved under strong functional constraints. In contrast, tertiary amine-detecting TAARs (TAAR5-9) have emerged more recently and the majority of them experienced higher rates of gene duplications. Protein members that belong to the tertiary amine-detecting TAAR group also showed the patterns of positive selection especially in the area surrounding the ligand-binding pocket, which could have affected ligand-binding activities and specificities. Expansions of the tertiary amine-detecting TAAR gene family may have played important roles in terrestrial adaptations of therian mammals. Molecular evolution of the TAAR gene family appears to be governed by a complex, species-specific, interplay between environmental and evolutionary factors.