Habitat-dependent diversification and parallel molecular evolution: Water scavenger beetles as a case study

Habitat shift is a key innovation that has contributed to the extreme diversification of insects. Most groups are well-adapted to more or less specific environments and shifts usually only happen between similar habitats. To colonize a profoundly different habitat type does not only present ecologic...

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Published in:Current zoology 2014-10, Vol.60 (5), p.561-570
Main Authors: Song, Ke-Qing, Xue, Huai-Jun, Beutel, Rolf G., Bai, Ming, Bian, Dong-Ju, Liu, Jie, Ruan, Yong-Ying, Li, Wen-Zhu, Jia, Feng-Long, Yang, Xing-Ke
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Language:English
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Summary:Habitat shift is a key innovation that has contributed to the extreme diversification of insects. Most groups are well-adapted to more or less specific environments and shifts usually only happen between similar habitats. To colonize a profoundly different habitat type does not only present ecological opportunities but also great challenges. We used Hydrophiloidea (water scavenger beetles) as a system to study transitions between terrestrial and aquatic environments. We estimated the diversification rate of different clades using phylogenetic trees based on a representative taxon sampling and six genes. We also investigated possible evolutionary changes in candidate genes following habitat shifts. Our results suggest that the diversification rate is relatively slow (0.039?0.050 sp/My) in the aquatic lineage, whereas it is distinctly increased in the secondarily terrestrial clade (0.055?0.075 sp/My). Our results also show that aquatic species have a G (Glycine) or S (Serine) amino acid at a given site of COI, while terrestrial species share an A (Alanine) amino acid with terrestrial outgroups. This indicates that habitat factors may create selection pressure on the evolution of functional genes and cause homoplasy in molecular evolution.
ISSN:1674-5507
2396-9814
DOI:10.1093/czoolo/60.5.561