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Functional changes of thermosensory molecules related to environmental adaptation

Elucidation of evolutionary trajectories by ancestral reconstruction

Date:
September 3, 2019
Source:
National Institutes of Natural Sciences
Summary:
Scientists have clarified the functional shift of thermal sensors among frog species adapted to different thermal niches and revealed the molecular basis for the shift in thermal perception related to environmental adaptation. They have found that thermal properties of heat sensors, TRPV1 and TRPA1, changed during adaptation processes to different thermal niches among clawed frog species.
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Animals have adapted to diverse thermal environments from cold to hot. During the course of thermal adaptation processes, preferred thermal ranges for survival shift among species adapted to different thermal niches. Accordingly, evolutionary changes of thermal perception must be required during thermal adaptation. To understand the molecular basis for the shift in thermal perception, the researchers compared the functional properties of thermal sensors among clawed frog species adapted to different thermal niches in Africa.

In clawed frog (genus Xenopus), TRPV1 and TRPA1 serve as heat sensors in thermal perception. In their previous study, heat responses of TRPV1 have been reported to differ between Xenopus laevis and Xenopus tropicalis adapted to cool and warm niches, respectively. Upon heat stimulation, X. laevis TRPV1 showed a maximum response from the first stimulation, while X. tropicalis TRPV1 showed only a small response in the first stimulation and its responses became gradually larger upon repeated heat stimulation.

In the present study, the researchers newly analyzed two species adapted to warm (Xenopus muelleri) and cool niches (Xenopus borealis). TRPV1 from these two species exhibited heat responses similar to X. laevis TRPV1. To elucidate the functional evolutionary process of TRPV1, ancestral proteins of TRPV1 was inferred and artificially reconstructed. Reconstructed ancestral TRPV1 also showed heat responses similar to Xenopus laevis, suggesting that TRPV1 heat responses specifically changed in the lineage leading to X. tropicalis. However, similar functional shift of TRPV1 did not occur from the ancestor to X. muelleri, therefore changes in the TRPV1 heat responses is not always linked with niche selection in the Xenopus evolutionary process.

On the other hand, comparison of TRPA1 among four Xenopus species revealed that heat-evoked activity of TRPA1 from cool-adapted species was considerably higher than that of TRPA1 from warm-adapted species. This finding suggests that the species adapted to cool niches increased the activity of a heat sensor (or vice versa) in order to sharply respond to heat exposure. Therefore, this study illuminated the importance of thermal sensors in environmental adaptation.


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Materials provided by National Institutes of Natural Sciences. Note: Content may be edited for style and length.


Journal Reference:

  1. Shigeru Saito, Claire T. Saito, Masafumi Nozawa, Makoto Tominaga. Elucidating the functional evolution of heat sensors among Xenopus species adapted to different thermal niches by ancestral sequence reconstruction. Molecular Ecology, 2019; 28 (15): 3561 DOI: 10.1111/mec.15170

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National Institutes of Natural Sciences. "Functional changes of thermosensory molecules related to environmental adaptation." ScienceDaily. ScienceDaily, 3 September 2019. <www.sciencedaily.com/releases/2019/09/190903091314.htm>.
National Institutes of Natural Sciences. (2019, September 3). Functional changes of thermosensory molecules related to environmental adaptation. ScienceDaily. Retrieved July 18, 2024 from www.sciencedaily.com/releases/2019/09/190903091314.htm
National Institutes of Natural Sciences. "Functional changes of thermosensory molecules related to environmental adaptation." ScienceDaily. www.sciencedaily.com/releases/2019/09/190903091314.htm (accessed July 18, 2024).

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