The evolution of temperature tolerance and invasiveness in a fluctuating thermal environment
The consequences of the climate change on species are still uncertain, despite of
intensive research. Currently, rising temperature is not the only concern, since the
climate change scenarios also predict increases in the amount of disturbances,
such as storms, floods, and thermal fluctuations. Disturbances have also been
shown to affect species’ evolution, for example by selecting for traits that are
advantageous in fluctuating environments but are also facilitating invasiveness. In
this thesis, I study the consequences of evolving in a fluctuating thermal
environment by utilizing bacterial microcosms. First I tested the effects of
fluctuating vs. constant temperature on the evolution of temperature tolerance,
both in one-species setting (I) and with multiple species (II). Then I studied how
pre-adaptations to fluctuating vs. constant temperature, together with
environmental conditions, affect invasion success (III). Additionally I also tested
the effects of propagule pressure and genetic diversity on invasion success (IV).
The results of the studies I and II show that constant and fluctuating thermal
environments require different kinds of adaptations, as measurements taken in
constant environments (traditional tolerance curve approach) did not reveal the
adaptations to fluctuating environment. In study III, I found that fluctuations
during invasion as well as pre-adaptations to fluctuating environment increased
the invasion success of the invader. However, in study IV, I did not find any clear
evidence that high propagule pressure or high genetic variance would have
increased invasion success. To conclude, the results in this thesis demonstrate that
adaptations that aid species to cope with disturbed environments can also lead to
increased invasiveness. Furthermore, these adaptations might not be detectable
using traditional measurement methods, which could, in the worst case, lead to
incorrect conclusions and management actions, when considering climate-change
driven extinction risks, or the effects of invasive species on natural environments.
...
Publisher
University of JyväskyläISBN
978-951-39-6459-7ISSN Search the Publication Forum
1456-9701Contains publications
- Article I: Ketola, T., Saarinen, K. 2015. Experimental evolution in fluctuating environments: tolerance measurements at constant temperatures incorrectly predict the ability to tolerate fluctuating temperatures. Journal of Evolutionary Biology 28: 800-806. DOI: 10.1111/jeb.12606
- Article II: Saarinen, K., Laakso, J., Lindström, L., Ketola, T. Constant and fluctuating thermal environments require different adaptations: evolution experiments with nine bacterial species. Submitted manuscript.
- Article III: Saarinen, K., Lindström, L., Ketola, T. Double-trouble with the climate change? Environmental fluctuations increase invasion success and select for more invasive genotypes. Manuscript.
- Article IV: Saarinen, K., Lindström, L., Ketola, T. Experimental invasions in bacterial microcosms: no effect of propagule pressure or genotypic diversity on invasion success. Manuscript.
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