Divergent selection along elevational gradients promotes genetic and phenotypic disparities among small mammal populations

Feijó, Anderson; Wen, Zhixin; Cheng, Jilong; Ge, Deyan; Xia, Lin; Yang, Qisen

doi:10.1002/ece3.5273

Cited by 14 publications

(14 citation statements)

References 104 publications

(250 reference statements)

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“…Geography and environment can both be effective barriers to gene flow between populations ( Hahn et al, 2012 ; Wang et al, 2013 ; Sexton et al, 2014 ; Reis et al, 2015 ; Antonelli, 2017 ; Feijó et al, 2019 ). These factors are not mutually exclusive and they are closely related directly or indirectly influencing the process of dispersal ( Wang et al, 2013 ; Huang et al, 2016 ), and we are expecting to find both geography and environment explaining the outlier genetic variation to a certain degree.…”

Section: Discussionmentioning

confidence: 99%

Ecological Factors Generally Not Altitude Related Played Main Roles in Driving Potential Adaptive Evolution at Elevational Range Margin Populations of Taiwan Incense Cedar (Calocedrus formosana)

et al. 2020

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Population diversification can be shaped by a combination of environmental factors as well as geographic isolation interacting with gene flow. We surveyed genetic variation of 243 samples from 12 populations of Calocedrus formosana using amplified fragment length polymorphism (AFLP) and scored a total of 437 AFLP fragments using 11 selective amplification primer pairs. The AFLP variation was used to assess the role of gene flow on the pattern of genetic diversity and to test environments in driving population adaptive evolution. This study found the relatively lower level of genetic diversity and the higher level of population differentiation in C. formosana compared with those estimated in previous studies of conifers including Cunninghamia konishii , Keteleeria davidiana var. formosana , and Taiwania cryptomerioides occurring in Taiwan. BAYESCAN detected 26 F ST outlier loci that were found to be associated strongly with various environmental variables using multiple univariate logistic regression, latent factor mixed model, and Bayesian logistic regression. We found several environmentally dependent adaptive loci with high frequencies in low- or high-elevation populations, suggesting their involvement in local adaptation. Ecological factors, including relative humidity and sunshine hours, that are generally not altitude related could have been the most important selective drivers for population divergent evolution in C. formosana . The present study provides fundamental information in relation to adaptive evolution and can be useful for assisted migration program of C. formosana in the future conservation of this species.

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Section: Discussionmentioning

confidence: 99%

Ecological Factors Generally Not Altitude Related Played Main Roles in Driving Potential Adaptive Evolution at Elevational Range Margin Populations of Taiwan Incense Cedar (Calocedrus formosana)

et al. 2020

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“…However, they can also be an important force driving genetic differentiation and speciation (Hewitt, 1996; Vences et al., 2009). For example, climatic variations along latitudinal gradients may affect organism functional traits such as phenology (Olsson & Ågren, 2002), physiology (Bognounou et al., 2010; De Frenne et al., 2012), and morphology (Feijó et al., 2019; Olsson & Ågren, 2002; Winn & Gross, 1993) and lead to plastic or genotypic shifts (Byars et al., 2007). Correlation analysis of neutral genetic variations versus geographic distances allows testing for IBD.…”

Section: Introductionmentioning

confidence: 99%

Drivers of population divergence and species differentiation in a recent group of indigenous orchids (Vanilla spp.) in Madagascar

Andriamihaja

Ramarosandratana

Grisoni

et al. 2021

Ecology and Evolution

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“…Specifically, we assess cranial evolution of Ochotona using geometric morphometric and phylogenetic comparative techniques to ask whether adaptations among high-elevation biota shown at the molecular and physiological levels also occur in resource-use phenotypic traits. We expect that species living at distinct altitudinal levels will show dissimilar morphological strategies to cope with distinct selection pressures, as recently shown at the population level for small mammals (Feijó et al, 2019).…”

Section: Introductionmentioning

confidence: 70%

“…Resourceuse phenotypic adaptations associated with restrictive habitats are well documented in subterranean (Da Silva et al, 2018;Marcy, Hadly, Sherratt, Garland, & Weisbecker, 2016;Sherratt, Gower, Klingenberg, & Wilkinson, 2014), rock-dwelling (Collar, Schulte, O'Meara, & Losos, 2010;Goodman, Miles, & Schwarzkopf, 2008;Revell, Johnson, Schulte, Kolbe, & Losos, 2007) and desert (Alhajeri & Steppan, 2018) animals. However, the few existing empirical studies on high-elevation morphological adaptations are mostly limited to intraspecific variation along mountain slopes, focusing on cold and desiccation tolerance (reviewed by Keller, Alexander, Holderegger, & Edwards, 2013; but see Feijó et al, 2019), lacking a macroevolutionary perspective. By focusing on only one level of adaptation (cellular), we are likely to overlook key evolutionary and ecological responses that allow animals to cope with multiple stresses in extreme-elevation environments.…”

Section: Introductionmentioning

confidence: 99%

Divergent adaptations in resource‐use traits explain how pikas thrive on the roof of the world

Feijó

Wen

et al. 2020

Functional Ecology

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Life in extreme environments is possible through multilevel adaptations to physical and biotic stresses. At high elevations, species face numerous challenges, besides low oxygen levels, but previous studies have focused on genetic and physiological adaptations to chronic hypoxia while overlooking other key strategies for thriving in alpine landscapes. Here, we investigate resource‐use trait adaptations to extreme elevations using pikas as a model, lagomorphs distributed up to 6,200 m and reaching maximum diversity on the Qinghai‐Tibet plateau, the highest plateau on Earth. Specifically, we assess cranial evolution in pikas using geometric morphometric and phylogenetic comparative techniques to determine whether adaptations among high‐elevation biota shown at the molecular and physiological levels also occur in resource‐use traits. We further explore the roles of two contrasting lifestyles (burrowing and rocky‐dwelling) in cranial evolution. We found that alpine species exhibit striking phenotypic specialization to distinct microhabitats. Contrary to physiological and genetic adaptive convergence, we show that the cranium has undergone adaptive divergence likely reflecting past resource competition in highlands and long‐term association with alpine landscapes. Our analyses also reveal that the evolution of burrowing lifestyle allows high‐elevation pikas to explore novel niches and boosts their phenotypic diversification. In addition to cold and hypoxia tolerance, high cranial specialization, the appearance of burrowing habits and strong niche separation explain how pikas overcome alpine stresses and flourish on the highest plateau on Earth. By contrast, when moving to spatially complex and heterogeneous vegetation zonation, pikas exhibit generalist skull forms able to exploit diverse habitats. These findings mirror previously reported intraspecific patterns in mammals, suggesting a general morphological response in resource‐exploiting traits to cope with distinct selection pressures across elevation zones. Phenotypic diversity is further constrained by rocky habitats, resulting in convergent skulls. Our study highlights that adaptations to extreme environments occur at multiple levels of organization, but can lead to distinct evolutionary paths depending on which selective forces they respond to. The evolution of burrowing behaviour represents a landmark in the evolutionary history of pikas. We further show that rocky habitats impose strong ecological pressures, leading to convergent responses in resource‐use traits, which is rarely documented in mammals.

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Divergent selection along elevational gradients promotes genetic and phenotypic disparities among small mammal populations

Cited by 14 publications

References 104 publications

Ecological Factors Generally Not Altitude Related Played Main Roles in Driving Potential Adaptive Evolution at Elevational Range Margin Populations of Taiwan Incense Cedar (Calocedrus formosana)

Ecological Factors Generally Not Altitude Related Played Main Roles in Driving Potential Adaptive Evolution at Elevational Range Margin Populations of Taiwan Incense Cedar (Calocedrus formosana)

Drivers of population divergence and species differentiation in a recent group of indigenous orchids (Vanilla spp.) in Madagascar

Divergent adaptations in resource‐use traits explain how pikas thrive on the roof of the world

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