Ecological and evolutionary responses of an arctic plant to variation in microclimate and soil |
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| Authors: | Niklas J. Wickander Pil U. Rasmussen Bryndís Marteinsdóttir Johan Ehrlén Ayco J. M. Tack |
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| Affiliation: | 1. Dept of Ecology, Environment and Plant Sciences, Stockholm Univ., Stockholm, Sweden;2. The National Research Centre for the Working Environment, Copenhagen, Denmark;3. The Soil Conservation Service of Iceland, Gunnarsholt, Hella, Iceland;4. Dept of Ecology, Environment and Plant Sciences, Stockholm Univ., Stockholm, Sweden Contribution: Conceptualization (equal), Writing - review & editing (supporting) |
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| Abstract: | The arctic and alpine regions are predicted to experience some of the highest rates of climate change, and the arctic vegetation is expected to be especially sensitive to such changes. Understanding the ecological and evolutionary responses of arctic plant species to changes in climate is therefore a key objective. Geothermal areas, where natural temperature gradients occur over small spatial scales, and without many of the confounding environmental factors present in latitudinal and other gradient studies, provide a natural experimental setting in which to examine the response of arctic–alpine plants to increasing temperatures. To test the ecological and evolutionary response of the circumpolar alpine bistort Persicaria vivipara to temperature, we collected plant material and soil from areas with low, intermediate and high soil temperatures and grew them at three different temperatures in a three-factorial growth chamber experiment. At higher experimental soil temperatures, sprouting was earlier and plants had more leaves. Sprouting was earlier in soil originating from intermediate temperature and plants had more leaves when grown in soil originating from low temperatures. We did not find evidence of local adaptation or genetic variation in reaction norms among plants originating from areas with low, intermediate and high soil temperature. Our findings suggest that the alpine bistort has a strong plastic response to warming, but that differences in soil temperature have not resulted in genetic differentiation. The lack of an observed evolutionary response may, for example, be due to the absence of temperature-mediated selection on P. vivipara, the low rate of sexual recombination, or high levels of gene flow balancing differences in selection. When placed within the context of other studies, we conclude that arctic–alpine plant species often show strong plastic responses to spring warming, while evidence of evolutionary responses varies among species. |
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| Keywords: | Bistorta vivipara geothermal systems local adaptation performance phenotypic plasticity soil temperature |
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