Alger Jorritsma’s scientific contributions

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Publications (2)


Some like it hot: adaptation to the urban heat island in common dandelion
  • Article

July 2024

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36 Reads

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1 Citation

Evolution Letters

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Ron Kraaiveld

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Alger Jorritsma

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[...]

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The Urban Heat Island Effect (UHIE) is a globally consistent pressure on biological species living in cities. Adaptation to the UHIE may be necessary for urban wild flora to persist in cities, but experimental evidence is scarce. Here, we report evidence of adaptive evolution in a perennial plant species in response to the UHIE. We collected seeds from common dandelion (Taraxacum officinale) individuals along an urban–rural gradient in the city of Amsterdam (The Netherlands). In common-environment greenhouse experiments, we assessed the effect of elevated temperatures on plant growth and the effect of vernalization treatments on flowering phenology. We found that urban plants accumulate more biomass at higher temperatures and require shorter vernalization periods, corresponding to milder winters, to induce flowering compared to rural plants. Differentiation was also observed between different intra-urban subhabitats, with park plants displaying a higher vernalization requirement than street plants. Our results show genetic differentiation between urban and rural dandelions in temperature-dependent growth and phenology, consistent with adaptive divergence in response to the UHIE. Adaptation to the UHIE may be a potential explanation for the persistence of dandelions in urban environments.


Fig. 1: Overview of the urban heat island effect (UHIE) in Amsterdam, The Netherlands. Locations in the sampling transect are indicated with small black triangles and are coloured based on the district they occur in. Two aspects of the urban heat island are shown: A -net increase in temperature due to the UHIE (retention of heat by buildings, streets and other man-made impermeable surfaces); B -effect of UHIE mitigation by surrounding vegetation and water. Both maps indicate annual averages. Mitigating effects shown in B are already discounted in the temperature increases shown in A. The transect was further divided into subhabitats based on field observations of the immediate surroundings (C-G). Histograms under the subhabitat pictures reflect the distribution of each subhabitat along the transect ranging from the start (left side
Fig. 2: Proportions of dandelions flowering under different vernalisation treatments, for plants originating from different locations along the urban-rural sampling transect . The number of flowering plants is plotted in colour against the total number of plants in the experiment (grey) in relation to: distance from the centre of the heat island (defined as the starting point of the transect) (A-C) with a bin size of 500m; urban, suburban and rural districts (D-F); and subhabitats (G-I). Top panels (A, D, G): no vernalization; middle panels (B, E, H): short (36 days) vernalization treatment; bottom panels (C, F, I): long (109 days) vernalization treatment. For panels B and C, probabilities of flowering at each distance from the centre of the heat island are plotted as predicted by the logistic regression models. Probability values indicate significance of flowering probability differences along the transect (A-C) or between habitats or districts (D-I).
Some like it hot: adaptation to the urban heat island in common dandelion
  • Preprint
  • File available

June 2023

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403 Reads

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1 Citation

The Urban Heat Island Effect (UHIE) is a globally consistent pressure on species living in cities. Rapid adaptation to the UHIE may be necessary for urban wild flora to persist in cities, but experimental evidence is lacking. Here, we report the first evidence of genetic differentiation in a plant species in response to the UHIE. We collected seeds from common dandelion ( Taraxacum officinale ) individuals along an urban-rural gradient in the city of Amsterdam (The Netherlands). In common-environment greenhouse experiments, we assessed the effect of elevated temperatures on plant growth and the effect of vernalisation treatments on flowering phenology. We found that urban plants accumulate more biomass at higher temperatures and require shorter vernalisation to induce flowering compared to rural plants. Differentiation was also observed between different intra-urban subhabitats, with park plants displaying a higher vernalisation requirement than street plants. Our results show strong differentiation between urban and rural dandelions in temperature-dependent growth and phenology, consistent with adaptive divergence in response to the UHIE. Rapid adaptation to the UHIE may be a potential explanation for the widespread success of dandelions in urban environments. Summary statement The urban heat island effect (UHIE) is the most prominent and globally consistent characteristic of environmental change due to urbanisation, severely impacting human populations in cities as well as the cohabiting wildlife. Despite the profoundly mitigating effect of vegetation on urban heat, evidence for plant adaptation to the UHIE has been lacking. Here we provide the first experimental evidence to date, demonstrating adaptation in urban dandelions in response to elevated temperatures, similar to the UHIE. We furthermore show an urban-rural differentiation in flowering response to shorter vernalisation times (cold winter period to activate the onset of flowering in early spring). Given the predominantly asexual apomictic mode of reproduction in dandelions, this evolution is likely the result of environmental filtering on a diverse population of clonal genotypes. We conclude that plant adaptation to the UHIE exists and recommend future studies to contrast our findings with those in outcrossing sexual plant systems. Studies of urban heat adaptation can bring impactful contributions to building climate change-resilient environments and plants should be an integral part of this research.

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