Potential contribution of floral thermogenesis to cold adaptation, distribution pattern, and population structure of thermogenic and non/slightly thermogenic Symplocarpus species.

The genus Symplocarpus in basal Araceae includes both thermogenic and non/slightly thermogenic species that prefer cold environments. If floral thermogenesis of Symplocarpus contributes to cold adaptation, it would be expected that thermogenic species have a larger habitat than non/slightly thermogenic species during an ice age, leading to increased genetic diversity in the current population. To address this question, potential distribution in past environment predicted by ecological niche modeling (ENM), genetic diversity, and population structure of chloroplast and genome-wide single nucleotide polymorphisms were compared between thermogenic Symplocarpus renifolius and non/slightly thermogenic Symplocarpus nipponicus. ENM revealed that the distribution of S. nipponicus decreased, whereas that of S. renifolius expanded in the Last Glacial Maximum. Phylogeographic analyses have shown that the population structures of the two species were genetically segmented and that the genetic diversity of S. renifolius was higher than that of S. nipponicus. The phylogenetic relationship between chloroplast and nuclear DNA is topologically different in the two species, which may be due to the asymmetric gene flow ubiquitously observed in plants. The results of this study imply that floral thermogenesis of Symplocarpus contributes to expanding the distribution during an ice age, resulting in increased genetic diversity due to cold adaptation. © 2023 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.

Citation

Mitsuhiko P Sato, Ayumi Matsuo, Koichi Otsuka, Kohei Takenaka Takano, Masayuki Maki, Kunihiro Okano, Yoshihisa Suyama, Yasuko Ito-Inaba. Potential contribution of floral thermogenesis to cold adaptation, distribution pattern, and population structure of thermogenic and non/slightly thermogenic Symplocarpus species. Ecology and evolution. 2023 Jul;13(7):e10319

PMID: 37456070

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