Gist of the experiment

There is now plenty of evidence that evolution can be a rapid process. Understanding how rapid evolutionary processes occur in nature is of utmost relevance to investigate adaptation to rapid climate change, which has already been documented for many species at the level of phenological and distribution range shifts (Parmesan & Yohe 2003; Franks et al. 2007; Charmantier et al. 2008; Hoffmann & Sgro 2011).

Last century’s breakthrough in evolutionary theory amounted to the focus on genetics as the basis of evolution and the redefinition of evolution in terms of allele frequency changes (Figure 1), influenced by neutral as well as selective forces (Fisher 1930; Wright 1942; Huxley 1942). Nowadays, well within the genomic era, our challenge is to experimentally demonstrate and extend those works by monitoring changes in allele frequencies in evolution experiments over multiple generations and selective environments in nature (e.g. Elena & Lenski 2003).

Allele frequency trajectories in a simulated Wright-Fisher population under drift and with 10 alleles naturally selected

With this aim, we are setting up a coordinated distributed experiment in which populations of the model plant Arabidopsis thaliana consisting of c. 200 sequenced ecotypes (1001 Genomes Consortium 2016) will be sown into replicated plots in different sites around the globe. By incorporating many sites with a broad range of environmental conditions, from southern Spain to the Scandinavian arctic, and by tracing the ecotype composition over multiple years by means of sequencing, we aim to gain insight into the roles of environmental variables in shaping temporal dynamics and spatial variation of population genomics.

We will apply pool-sequencing of plants throughout their reproductive stage to identify successful ecotypes, their phenological timing, and their genomic makeup. As predicted by local adaptation theory, we expect that success under certain temperature, moisture and soil composition will be related to the environment of origin and phenotypic characteristics of each ecotype. However, in contrast with other common garden experiments, we will directly measure the dynamics of natural selection and adaptation to each of the environments where the experiment is taking place.

study_site_tub Exemplary evolution experiment plot with Arabidopsis thaliana plants

The Protocol

You can find the general GrENE-net protocol here.

study_site_tub Photo of the study site in Tubingen, Germany (2017)

Policy and ethics statement

Read the full policy and ethics statement here.

Note on post-experiment handling of genetic material:

Uncontrolled transplant experiments can lead to genetic contamination of local populations (Rogers & Siemann 2004; Saltonstall K 2002) and to species invasions (Seebens et al. 2017). Although A. thaliana is a cosmopolitan plant native or naturalized to all countries where GrENE-net experiments are carried out, we ask participants to grow their replicate populations in a controlled area, preferably an institution’s ground, free from natural A. thaliana populations. Furthermore, after the experiment all used soil and plant material will be incinerated and a treatment herbicide will be used in a secured perimeter to eliminate any trace of planted seeds, as has been done before in similar outdoor experiments (Exposito-Alonso et al. 2017; Exposito-Alonso et al. 2018).

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