Abstract
Genetic adaptation to extremes is a fascinating topic. Nevertheless, few studies have explored the genetic adaptation of closely related species respectively inhabiting distinct extremes. With deep transcriptome sequencing, we attempt to detect the genetic architectures of tadpoles of five closely related toad species adapted to the Tibetan Plateau, middle-altitude mountains and karst caves. Molecular evolution analyses indicated that not only the number of fast evolving genes (FEGs), but also the functioning coverage of FEGs, increased with elevation. Enrichment analyses correspondingly revealed that the highland species had most of the FEGs involved in high-elevation adaptation, for example, amino acid substitutions of XRCC6 in its binding domains might improve the capacity of DNA repair of the toad. Yet, few FEGs and positively selected genes (PSGs) involved in high-elevation adaptation were identified in the cave species, and none of which potentially contributed to cave adaptation. Accordingly, it is speculated that in the closely related toad tadpoles, genetic selection pressures increased with elevation, and cave adaptation was most likely derived from other factors (e.g., gene loss, pseudogenization or deletion), which could not be detected by our analyses. The findings supply a foundation for understanding the genetic adaptations of amphibians inhabiting extremes.
Highlights
The genetic adaptations of organisms inhabiting extreme environments have received increasing attention [1]
113,009, 130,280, 127,614, 104,456, 124,330, and 156,313 unigenes were obtained from transcriptomes of O. rhodostigmatus, O. major, S. boulengeri, M. omeimontis, O. omeimontis, and O. popei, respectively
Based on single-copy orthologous genes resulting from deep transcriptome sequencing, we explored the genetic profiles of tadpoles of five closely related toad species respectively adapted to the Tibetan Plateau, middle-elevation mountains, and karst cave systems
Summary
The genetic adaptations of organisms inhabiting extreme environments have received increasing attention [1]. It is suggested that species from more fluctuating environments show more rapid genetic evolution that might preadapt them to extremes [2,3]. Exploring how genetic evolution differs among extremes is undoubtedly interesting. The various extreme geological environments in China (e.g., Tibetan Plateau, Taklimakan desert and Southwest karst caves) harbors a mass of specialized species adapted to these extremes [4]. These conditions facilitate studies on the genetic backgrounds of lives adapted to distinct extreme environments
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