Your search keyword '"Johan, Ehrlén"' showing total 170 results

1. Microclimate influences plant reproductive performance via an antagonistic interaction

Author

Alicia Valdés and Johan Ehrlén

Subjects

Ecology, Evolution, Behavior and Systematics

Published

2022

2. Selection against early flowering in geothermally heated soils is associated with pollen but not prey availability in a carnivorous plant

Author

Alicia Valdés, Vigdís F. Helmutsdóttir, Bryndís Marteinsdottir, and Johan Ehrlén

Subjects

Soil, Carnivorous Plant, Climate Change, Temperature, Genetics, Pollen, Flowers, Seasons, Plant Science, Plants, Ecology, Evolution, Behavior and Systematics

Abstract

In high-latitude environments, plastic responses of phenology to increasing spring temperatures allow plants to extend growing seasons while avoiding late frosts. However, evolved plasticity might become maladaptive if climatic conditions change and spring temperatures no longer provide reliable cues for conditions important for fitness. Maladaptative phenological responses might be related to both abiotic factors and mismatches with interacting species. When mismatches arise, we expect selection to favor changes in phenology.We combined observations along a soil temperature gradient in a geothermally heated area with pollen and prey supplementation experiments and examined how phenotypic selection on flowering time in the carnivorous plant Pinguicula vulgaris depends on soil temperature, and pollen and prey availability.Flowering advanced and fitness decreased with increasing soil temperature. However, in pollen-supplemented plants, fitness instead increased with soil temperature. In heated soils, there was selection favoring later flowering, while earlier flowering was favored in unheated soils. This pattern remained also after artificially increasing pollen and prey availability.Plant-pollinator mismatches can be an important reason why evolved plastic responses of flowering time to increasing spring temperatures become maladaptive under novel environmental conditions, and why there is selection to delay flowering. In our study, selection for later flowering remained after artificially increasing pollen availability, suggesting that abiotic factors also contribute to the observed selection. Identifying the factors that make evolved phenological responses maladaptive under novel conditions is fundamental for understanding and predicting evolutionary responses to climate warming.

Published

2022

3. Widespread latitudinal asymmetry in the performance of marginal populations:A meta-analysis

Author

Fernando Pulido, Bastien Castagneyrol, Francisco Rodríguez‐Sánchez, Yónatan Cáceres, Adara Pardo, Eva Moracho, Johannes Kollmann, Fernando Valladares, Johan Ehrlén, Alistair S. Jump, Jens‐Christian Svenning, Arndt Hampe, Ministerio de Economía y Competitividad (España), Natural Environmental Research Council, Institut National de Recherche pour l’agriculture, l’alimentation et l’environnement, Universidad de Sevilla, and Danish National Research Foundation

Subjects

Global and Planetary Change, Demographic rates, population performance, Ecology, demographic rates, range edge, range margin, range shift, Centre-periphery hypothesis, climate change, centre-periphery hypothesis, Range shift, Range edge, Climate change, Ecology, Evolution, Behavior and Systematics

Abstract

[Aim]: Range shifts are expected to occur when populations at one range margin per-form better than those at the other margin, yet no global trend in population per-formances at range margins has been demonstrated empirically across a wide range of taxa and biomes. Here we test the prediction that, if impacts of ongoing climate change on performance in marginal populations are widespread, then populations from the high- latitude margin (HLM) should perform as well as or better than central populations, whereas low- latitude margin (LLM) populations should perform worse., [Location]: Global., [Time period]: 1995–2019., [Major taxa studied]: Plants and animals., [Methods]: To test our prediction, we used a meta-analysis to quantify empirical sup-port for asymmetry in the performance of high- and low- latitude margin populations compared to central populations. Performance estimates (survival, reproduction, or lifetime fitness) for populations occurring in their natural environment were derived from 51 papers involving 113 margin-centre comparisons from 54 species and 705 populations from the Americas, Europe, Africa and Australia. We then related these performance differences to climatic differences among populations. We also tested whether patterns are consistent across taxonomic kingdoms (plants vs animals) and across realms (marine vs terrestrial)., [Results]: Populations at margins performed significantly worse than central popula-tions, and this trend was primarily driven by the low- latitude margin. Although the dif-ference was of small magnitude, it was largely consistent across biological kingdoms and realms. Differences in performance were weakly (p= .08) related to the differ-ence in average temperatures between central and marginal populations., [Main conclusions]: The observed asymmetry in performance in marginal populations is consistent with predictions about the effects of global climate change, though fur-ther research is needed to confirm the effect of climate. It indicates that changes in demographic rates in marginal populations can serve as early-warning signals of impending range shifts, This study was funded by Nord Forsk grant no. 80167 to the NORA Consortium (Nordic Network for the Study of Species Range Dynamics, 2009–2012), by projects POPULIM (CGL2010-22180) and PERSLIM (CGL2010-18381) of the Spanish Ministerio de Ciencia e Innovación, the EU ERA- net BiodivERsA project BeFoFu (via funding to ASJ by Natural Environmental Research Council grant NE/G002118/1) and the Institut National de Recherche pour l’agriculture, l’alimentation et l’environnement Assessing Climate Change Adaptation Framework project FORADAPT. FRS was funded by a postdoctoral fellow-ship from the Spanish Ministerio de Economía y Competitividad (FPD2013-16756) and a Talent Attraction grant from the VI Plan Propio de Investigación at Universidad de Sevilla (VIPPIT-2018- IV.2). JCS considers this work a contribution to his VILLUM Investigator project ‘Biodiversity Dynamics in a Changing World’, funded by VILLUM FONDEN (grant 16549), and Center for Ecological Dynamics in a Novel Biosphere (ECONOVO), funded by Danish National Research Foundation (grant DNRF173).

Published

2023

4. Interactive effects of drought and edge exposure on old-growth forest understory species

Author

Irena A. Koelemeijer, Johan Ehrlén, Mari Jönsson, Pieter De Frenne, Peter Berg, Jenny Andersson, Henrik Weibull, and Kristoffer Hylander

Subjects

IMPACTS, Extreme weather, PATCHES, Ecology, Edge effects, Geography, Planning and Development, Oceanografi, hydrologi och vattenresurser, Microclimate, LICHENS, CLIMATE, Oceanography, Hydrology and Water Resources, WOODLAND KEY HABITATS, SUMMER DROUGHT, BOREAL FOREST, Fragmentation, Earth and Environmental Sciences, BIODIVERSITY, Land-use, BRYOPHYTES, RESPONSES, Nature and Landscape Conservation

Abstract

Context Both climatic extremes and land-use change constitute severe threats to biodiversity, but their interactive effects remain poorly understood. In forest ecosystems, the effects of climatic extremes can be exacerbated at forest edges. Objectives We explored the hypothesis that an extreme summer drought reduced the richness and coverage of old-growth forest species, particularly in forest patches with high edge exposure. Methods Using a high-resolution spatially explicit precipitation dataset, we could detect variability in drought intensity during the summer drought of 2018. We selected 60 old-growth boreal forest patches in central Sweden that differed in their level of drought intensity and amount of edge exposure. The year after the drought, we surveyed red-listed and old-growth forest indicator species of vascular plants, lichens and bryophytes. We assessed if species richness, composition, and coverage were related to drought intensity, edge exposure, and their interaction. Results Species richness was negatively related to drought intensity in forest patches with a high edge exposure, but not in patches with less edge exposure. Patterns differed among organism groups and were strongest for cyanolichens, epiphytes associated with high-pH bark, and species occurring on convex substrates such as trees and logs. Conclusions Our results show that the effects of an extreme climatic event on forest species can vary strongly across a landscape. Edge exposed old-growth forest patches are more at risk under extreme climatic events than those in continuous forests. This suggest that maintaining buffer zones around forest patches with high conservation values should be an important conservation measure.

Published

2022

5. Forest edge effects on moss growth are amplified by drought

Author

Irena Adia Koelemeijer, Johan Ehrlén, Pieter De Frenne, Mari Jönsson, Peter Berg, and Kristoffer Hylander

Subjects

Ecology

Abstract

Forest fragmentation increases the amount of edges in the landscape. Differences in wind, radiation, and vegetation structure create edge-to-interior gradients in forest microclimate, and these gradients are likely to be more pronounced during droughts and heatwaves. Although the effects of climate extremes on edge influences have potentially strong and long-lasting impacts on forest understory biodiversity, they are not well understood and are not often considered in management and landscape planning. Here we used a novel method of retrospectively quantifying growth to assess biologically relevant edge influences likely caused by microclimate using Hylocomium splendens, a moss with annual segments. We examined how spatio-temporal variation in drought across 3 years and 46 sites in central Sweden, affected the depth and magnitude of edge influences. We also investigated whether edge effects during drought were influenced by differences in forest structure. Edge effects were almost twice as strong in the drought year compared to the non-drought years, but we did not find clear evidence that they penetrated deeper into the forest in the drought year. Edge influences were also greater in areas that had fewer days with rain during the drought year. Higher levels of forest canopy cover and tree height buffered the magnitude of edge influence in times of drought. Our results demonstrate that edge effects are amplified by drought, suggesting that fragmentation effects are aggravated when droughts become more frequent and severe. Our results suggest that dense edges and buffer zones with high canopy cover can be important ways to mitigate negative drought impacts in forest edges.

Published

2023

6. Life-history characteristics and historical factors are important to explain regional variation in reproductive traits and genetic diversity in perennial mosses

Author

Irene Bisang, Johan Ehrlén, and Lars Hedenäs

Subjects

Plant Science

Abstract

Background and Aims Plants have evolved an unrivalled diversity of reproductive strategies, including variation in the degree of sexual vs. clonal reproduction. This variation has important effects on the dynamics and genetic structure of populations. We examined the association between large-scale variation in reproductive patterns and intraspecific genetic diversity in two moss species where sex is manifested in the dominant haploid generation and sex expression is irregular. We predicted that in regions with more frequent realized sexual reproduction, populations should display less skewed sex ratios, should more often express sex and should have higher genetic diversity than in regions with largely clonal reproduction. Methods We assessed reproductive status and phenotypic sex in the dioicous long-lived Drepanocladus trifarius and D. turgescens, in 248 and 438 samples across two regions in Scandinavia with frequent or rare realized sexual reproduction, respectively. In subsets of the samples, we analysed genetic diversity using nuclear and plastid sequence information and identified sex with a sex-specific molecular marker in non-reproductive samples. Key Results Contrary to our predictions, sex ratios did not differ between regions; genetic diversity did not differ in D. trifarius and it was higher in the region with rare sexual reproduction in D. turgescens. Supporting our predictions, relatively more samples expressed sex in D. trifarius in the region with frequent sexual reproduction. Overall, samples were mostly female. The degree of sex expression and genetic diversity differed between sexes. Conclusions Sex expression levels, regional sex ratios and genetic diversity were not directly associated with the regional frequency of realized sexual reproduction, and relationships and variation patterns differed between species. We conclude that a combination of species-specific life histories, such as longevity, overall degree of successful sexual reproduction and recruitment, and historical factors are important to explain this variation. Our data on haploid-dominated plants significantly complement plant reproductive biology.

Published

2023

7. Changes in forest structure drive temperature preferences of boreal understorey plant communities

Author

Ditte Marie Christiansen, Lars Lønsmann Iversen, Johan Ehrlén, and Kristoffer Hylander

Subjects

Ecology, Plant Science, Ecology, Evolution, Behavior and Systematics

Abstract

The local climate in forest understories can deviate substantially from ambient conditions. Moreover, forest microclimates are often characterized by cyclic changes driven by management activities such as clear-cutting and subsequent planting. To understand how and why understorey plant communities change, both ambient climate change and temporal variation in forest structure have to be considered. We used inventories from 11,436 productive forest sites in Sweden repeated every 10th year 1993–2017 to examine how variation in forest structure influences changes in the average value of minimum and maximum temperature preferences of all species in a community, that is, community temperature indices (CTIs). We then evaluated to what extent these changes were driven by local extinctions and colonizations, respectively, and to what extent the difference in CTI value between two inventories was related to changes in forest density and in macroclimate. Lastly, we tested whether effects on CTI change by these two drivers were modified by topography, soil moisture and tree species composition. CTI values of the understorey plant communities increased after clear-cutting, and decreased during periods when the forest grew denser. During the period immediately after clear-cutting, changes were predominately driven by colonizations of species with a preference for higher temperatures. During the forest regeneration phase, both colonizations by species preferring lower temperatures and local extinctions of species preferring higher temperatures increased. The change in understorey CTI over 10-year periods was explained more by changes in forest density, than by changes in macroclimate. Soil moisture, topography and forest tree species composition modified to some extent the effects of changes in forest density and in macroclimate on understorey CTI values. Synthesis. Via stand manipulation, forest management impacts the effects of regional climate on understorey plant communities. This implies that forest management by creating denser stands locally even can counterbalance the effects of regional changes in climate. Consequently, interpretations of changes in the mean temperature preference of species in forest understorey communities should take forest management regimes into account.

Published

2021

8. Pathogen infection influences the relationship between spring and autumn phenology at the seedling and leaf level

Author

Johan Ehrlén, Laura J. A. van Dijk, Jessie Mutz, Ayco J. M. Tack, and Ryan McClory

Subjects

0106 biological sciences, Abiotic component, biology, Phenology, fungi, food and beverages, 15. Life on land, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Quercus robur, Horticulture, Germination, Seedling, Shoot, Colonization, Ecology, Evolution, Behavior and Systematics, Powdery mildew, 010606 plant biology & botany

Abstract

Seasonal life history events are often interdependent, but we know relatively little about how the relationship between different events is influenced by the abiotic and biotic environment. Such knowledge is important for predicting the immediate and evolutionary phenological response of populations to changing conditions. We manipulated germination timing and shade in a multi-factorial experiment to investigate the relationship between spring and autumn phenology in seedlings of the pedunculate oak, Quercus robur, and whether this relationship was mediated by natural colonization of leaves by specialist fungal pathogens (i.e., the oak powdery mildew complex). Each week delay in germination corresponded to about 2 days delay in autumn leaf senescence, and heavily shaded seedlings senesced 5-8 days later than seedlings in light shade or full sun. Within seedlings, leaves on primary-growth shoots senesced later than those on secondary-growth shoots in some treatments. Path analyses demonstrated that germination timing and shade affected autumn phenology both directly and indirectly via pathogen load, though the specific pattern differed among and within seedlings. Pathogen load increased with later germination and greater shade. Greater pathogen load was in turn associated with later senescence for seedlings, but with earlier senescence for individual leaves. Our findings show that relationships between seasonal events can be partly mediated by the biotic environment and suggest that these relationships may differ between the plant and leaf level. The influence of biotic interactions on phenological correlations across scales has implications for understanding phenotypic variation in phenology and for predicting how populations will respond to climatic perturbation.

Published

2021

9. Impacts of soil temperature, phenology and plant community composition on invertebrate herbivory in a natural warming experiment

Author

Bryndís Marteinsdóttir, Vigdís F. Helmutsdóttir, Sinikka I. Robinson, Johan Ehrlén, Eoin J. O'Gorman, Emily Warner, Ecosystems and Environment Research Programme, and Environmental Change Research Unit (ECRU)

Subjects

Hengill, life history, 0106 biological sciences, 010504 meteorology & atmospheric sciences, INCREASES, DIVERSITY, Biology, global warming, 010603 evolutionary biology, 01 natural sciences, Subarctic, GLOBAL CHANGE, Ecology, Evolution, Behavior and Systematics, natural experiment, trophic interactions, 0105 earth and related environmental sciences, Herbivore, CLIMATE-CHANGE, Resistance (ecology), Ecology, Phenology, geothermal gradient, fungi, BIOTIC INTERACTIONS, food and beverages, Plant community, INSECT, Vegetation, 15. Life on land, Subarctic climate, climate change, 13. Climate action, 1181 Ecology, evolutionary biology, Litter, GROWTH, Forb, RESISTANCE, TRAITS, RESPONSES

Abstract

Species and community-level responses to warming are well documented, with plants and invertebrates known to alter their range, phenology or composition as temperature increases. The effects of warming on biotic interactions are less clearly understood, but can have consequences that cascade through ecological networks. Here, we used a natural soil temperature gradient of 5–35°C in the Hengill geothermal valley, Iceland, to investigate the effects of temperature on plant community composition and plant–invertebrate interactions. We quantified the level of invertebrate herbivory on the plant community across the temperature gradient and the interactive effects of temperature, plant phenology (i.e. development stage) and vegetation community composition on the probability of herbivory for three ubiquitous plant species, Cardamine pratensis, Cerastium fontanum and Viola palustris. We found that the percentage cover of graminoids and forbs increased, while the amount of litter decreased, with increasing soil temperature. Invertebrate herbivory also increased with soil temperature at the plant community level, but this was underpinned by different effects of temperature on herbivory for individual plant species, mediated by the seasonal development of plants and the composition of the surrounding vegetation. This illustrates the importance of considering the development stage of organisms in climate change research given the variable effects of temperature on susceptibility to herbivory at different ontogenetic stages.

Published

2021

10. Direct and insect‐mediated effects of pathogens on plant growth and fitness

Author

Johan Ehrlén, Laura J. A. van Dijk, and Ayco J. M. Tack

Subjects

Plant growth, Ecology, biology, Pollinator, media_common.quotation_subject, Botany, Plant Science, Insect, Anemone nemorosa, biology.organism_classification, Ecology, Evolution, Behavior and Systematics, media_common

Published

2021

11. Positive indirect effects more than balance negative direct effects of ungulate grazers on population growth of a grassland herb

Author

Thomas J. Richards, Michel Thomann, Johan Ehrlén, and Jon Ågren

Abstract

Herbivores can affect plant population dynamics both directly because of the damage they inflict, and indirectly by moderating conditions for plant recruitment, competition and other biotic interactions. Still, the relative importance of indirect effects of herbivores on plant population dynamics is poorly known.We quantified direct and indirect effects of ungulate grazers on population growth rate of the short-lived perennial herb Primula farinosa, using integral projection models based on demographic data collected over 7 years in exclosures and open control plots at nine grassland sites in southern Sweden. In addition, we explored the mechanisms behind indirect effects with simulations.Grazers had negative direct effects on P. farinosa population growth rate, but these were more than balanced by positive indirect effects. The positive indirect effects were mainly linked to improved conditions for plant recruitment. Simulations indicated that indirect effects of ungulate grazers on population growth rate via interactions with pollinators, seed predators, and small herbivores were weak in this system.Synthesis. The results demonstrate that a full understanding of the effects of grazing on plant population dynamics requires that both direct and indirect effects are identified and quantified. Plant species vary considerably in their response to shifts in grazing regime. Our study sets an example for how the causes of such variation can be assessed, and thus providing a better understanding of the variable effects of herbivores on plant fitness, abundance and distribution.

Published

2022

12. Local distribution patterns of fleshy‐fruited woody plants – testing the orchard hypothesis

Author

Matilda Arnell, Ove Eriksson, and Johan Ehrlén

Subjects

Density dependence, Ecology, business.industry, Distribution (economics), Point pattern analysis, Biology, Orchard, business, Ecology, Evolution, Behavior and Systematics, Woody plant

Published

2020

13. <scp>lefko3</scp> : Analysing individual history through size‐classified matrix population models

Author

Shun Kurokawa, Richard P. Shefferson, and Johan Ehrlén

Subjects

education.field_of_study, Ecological Modeling, Population, Matrix projection, Statistical physics, education, Matrix population models, Biological sciences, Ecology, Evolution, Behavior and Systematics, Mathematics

Abstract

1. The histories of individuals impact the dynamics of their populations. Matrix projection models (MPMs) are used to analyse population dynamics, but are not structured to incorporate these influe ...

Published

2020

14. Ecological and evolutionary responses of an arctic plant to variation in microclimate and soil

Author

Pil U. Rasmussen, Ayco J. M. Tack, Niklas Jan Wickander, Johan Ehrlén, and Bryndís Marteinsdóttir

Subjects

Phenotypic plasticity, Soil temperature, Variation (linguistics), biology, Arctic, Ecology, Microclimate, biology.organism_classification, Ecology, Evolution, Behavior and Systematics, Bistorta vivipara, Local adaptation

Published

2020

15. Climate drives among‐year variation in natural selection on flowering time

Author

Alicia Valdés and Johan Ehrlén

Subjects

0106 biological sciences, Phenotypic plasticity, Natural selection, Ecology, Phenology, Climate Change, Reproduction, 010604 marine biology & hydrobiology, Lathyrus vernus, Temperature, Climate change, Flowers, Biology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Phenotype, Trait, Seasons, Precipitation, Selection, Genetic, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm)

Abstract

To predict long-term responses to climate change, we need to understand how changes in temperature and precipitation elicit both immediate phenotypic responses and changes in natural selection. We used 22 years of data for the perennial herb Lathyrus vernus to examine how climate influences flowering phenology and phenotypic selection on phenology. Plants flowered earlier in springs with higher temperatures and higher precipitation. Early flowering was associated with a higher fitness in nearly all years, but selection for early flowering was significantly stronger in springs with higher temperatures and lower precipitation. Climate influenced selection through trait distributions, mean fitness and trait-fitness relationships, the latter accounting for most of the among-year variation in selection. Our results show that climate both induces phenotypic responses and alters natural selection, and that the change in the optimal phenotype might be either weaker, as for spring temperature, or stronger, as for precipitation, than the optimal response.

Published

2020

16. Single, but not dual, attack by a biotrophic pathogen and a sap-sucking insect affects the oak leaf metabolome

Author

Laura J A, van Dijk, Emilia D E, Regazzoni, Benedicte R, Albrectsen, Johan, Ehrlén, Ahmed, Abdelfattah, Hans, Stenlund, Katharina, Pawlowski, and Ayco J M, Tack

Abstract

Plants interact with a multitude of microorganisms and insects, both below- and above ground, which might influence plant metabolism. Despite this, we lack knowledge of the impact of natural soil communities and multiple aboveground attackers on the metabolic responses of plants, and whether plant metabolic responses to single attack can predict responses to dual attack. We used untargeted metabolic fingerprinting (gas chromatography-mass spectrometry, GC-MS) on leaves of the pedunculate oak

Published

2022

17. Weather-driven demography and population dynamics of an endemic perennial plant during a 34-year period

Author

Johan Ehrlén, Torbjörn Lindell, and Johan P. Dahlgren

Subjects

education.field_of_study, demography, flowering, Ecology, Perennial plant, Population, Climate change, Plant Science, precipitation, Geography, climate change, vital rates, Period (geology), population dynamics, Vital rates, Pulsatilla, education, Ecology, Evolution, Behavior and Systematics, integral projection model

Abstract

Increased anthropogenic influence on the environment has accentuated the need to assess how climate and other environmental factors drive vital rates and population dynamics of different types of organisms. However, to allow distinction between the effects of multiple correlated variables, and to capture the effects of rare and extreme climatic conditions, studies extending over decades are often necessary. In this study, we used an individual-based dataset collected in three populations of Pulsatilla vulgaris subsp. gotlandica during 34 years, to explore the effects of variation in precipitation and temperature on vital rates and population dynamics. Most of the observed conspicuous variation in flowering among years was associated with differences in precipitation and temperature in the previous summer and autumn with a higher incidence of flowering following summers with high precipitation and low temperatures. In contrast, climatic variables had no significant effects on individual growth or survival. Although the weather-driven variation in flowering had only moderate absolute effects on the population growth rate, simulated persistent changes in average precipitation and temperature resulted in considerable reductions in population sizes compared with current conditions. Analyses carried out with subsets of data consisting of 5 and 10 years yielded results that strongly deviated from those based on the full dataset. Synthesis. The results of this study illustrate the importance of long-term demographic monitoring to identify key climatic variables affecting vital rates and driving population dynamics in long-lived organisms.

Published

2022

18. Spring and autumn phenology in an understory herb are uncorrelated and driven by different factors

Author

Giulia Zacchello, Johan Ehrlén, Daniela Guasconi, Johan P. Dahlgren, and Elsa Fogelström

Subjects

life history, soil temperature, leaf expansion, Climate, Climate Change, Lathyrus vernus, Growing season, plant phenology, Plant Science, shoot senescence, developmental correlation, Trees, Grazing, shoot coloration, Genetics, Temperate climate, Ecology, Evolution, Behavior and Systematics, Ekologi, Lathyrus, Ecology, biology, Phenology, Temperature, Botany, Fabaceae, Botanik, Understory, biology.organism_classification, Plant Leaves, climate change, Natural population growth, Shoot, Seasons

Abstract

PREMISE: Climate warming has altered the start and end of growing seasons in temperate regions. Ultimately, these changes occur at the individual level, but little is known about how previous seasonal life history events, temperature, and plant resource state simultaneously influence the spring and autumn phenology of plant individuals.METHODS: We studied the relationships between the timing of leaf-out and shoot senescence over three years in a natural population of the long-lived understory herb Lathyrus vernus and investigated the effects of spring temperature, plant size, reproductive status and grazing on spring and autumn phenology.KEY RESULTS: The timing of leaf-out and senescence were consistent within individuals among years. Leaf-out and senescence were not correlated with each other within years. Larger plants both leafed out and senesced later, and there was no effect of size on growing season length. Reproductive plants leafed out earlier and had longer growing seasons than non-reproductive plants. Grazing had no detectable effects on phenology. Colder spring temperatures delayed senescence in two of three study years.CONCLUSION: The timing of seasonal events, such as leaf-out and senescence in plants can be expressed largely independently within and among seasons and are influenced by different factors. Growing season start and length can often be condition-dependent and dependent on plant reproductive status. To more accurately predict species and community responses to environmental variation, knowledge about the drivers of growing season length of individuals is essential. This article is protected by copyright. All rights reserved.

Published

2022

19. Author response for 'Changes in forest structure drive temperature preferences of boreal understory plant communities'

Author

null Ditte Marie Christiansen, null Lars Lønsmann Iversen, null Johan Ehrlén, and null Kristoffer Hylander

Published

2021

20. Author response for 'Weather driven demography and population dynamics of an endemic perennial plant during a 34‐year period'

Author

null Torbjörn Lindell, null Johan Ehrlén, and null Johan P. Dahlgren

Published

2021

21. Simultaneous selection on vegetative and reproductive phenology in a perennial herb

Author

Elsa Fogelström, Giulia Zacchello, and Johan Ehrlén

Subjects

flowering phenology, Ekologi, Ecology, indirect selection, fungi, leaf-out, phenotypic selection, food and beverages, opposing selection, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, correlational selection

Abstract

The timing of different life history events are often correlated, and selection might only rarely be exerted independently on the timing of a single event. In plants, phenotypic selection has often been shown to favour earlier flowering. However, little is known about to what extent this selection acts directly vs. indirectly via vegetative phenology, and if selection on the two traits is correlational. We estimated direct, indirect and correlational phenotypic selection on vegetative and reproductive phenology over three years for the perennial herb Lathyrus vernus. Direct selection favoured earlier flowering and shorter timespans between leaf-out and flowering in all years. However, early flowering was associated with early leaf-out, and the direction of selection on leaf-out day varied among years. As a result, selection on leaf-out weakened selection for early flowering in one of the study years. We found no evidence of correlational selection. Our results highlight the importance of including temporally correlated traits when exploring selection on the phenology of seasonal events.

Published

2021

22. Warm range margin of boreal bryophytes and lichens not directly limited by temperatures

Author

Eric Meineri, Sonia Merinero, Miska Luoto, Caroline Greiser, Johan Ehrlén, Kristoffer Hylander, Benny Willman, Department of Geosciences and Geography, Helsinki Institute of Sustainability Science (HELSUS), BioGeoClimate Modelling Lab, Department of Ecology, Environment and Plant Sciences [Stockholm], Stockholm University, Helsingin yliopisto = Helsingfors universitet = University of Helsinki, Institut méditerranéen de biodiversité et d'écologie marine et continentale (IMBE), Avignon Université (AU)-Aix Marseille Université (AMU)-Institut de recherche pour le développement [IRD] : UMR237-Centre National de la Recherche Scientifique (CNRS), University of Helsinki, Universidad de Sevilla. Departamento de Biología Vegetal y Ecología, and Royal Swedish Academy of Sciences

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Range (biology), Species distribution, Microclimate, Biotic interactions, Plant Science, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, biotic interactions, Margin (machine learning), Plant–climate interactions, MICROCLIMATE, PLANTS, Herbivory, MICROREFUGIA, plant-climate interactions, transplant experiment, Lichen, Water content, Rear edge, Transplant experiment, Ecology, Evolution, Behavior and Systematics, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, Herbivore, CLIMATE-CHANGE, Ecology, herbivory, REFUGIA, rear edge, SPECIES DISTRIBUTIONS, 15. Life on land, FOREST, Boreal, EDGE, 1181 Ecology, evolutionary biology, Environmental science, species distribution, BIODIVERSITY, Soil moisture, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, soil moisture, RESPONSES

Abstract

Species at their warm range margin are potentially threatened by higher temperatures, but may persist in microrefugia. Whether such microsites occur due to more suitable microclimate or due to lower biotic pressure from, for example competitive species, is still not fully resolved. We examined whether boreal bryophytes and lichens show signs of direct climate limitation, that is whether they perform better in cold and/or humid microclimates at their warm range margin. We transplanted a moss, a liverwort and a lichen to 58 boreal forest sites with different microclimates at the species' southern range margin in central Sweden. Species were grown in garden soil patches to control the effects of competitive exclusion and soil quality. We followed the transplanted species over three growing seasons (2016–2018) and modelled growth and vitality for each species as a function of subcanopy temperature, soil moisture, air humidity and forest type. In 2018, we also recorded the cover of other plants having recolonized the garden soil patches and modelled this potential future competition with the same environmental variables plus litter. Species performance increased with warmer temperatures, which was often conditional on high soil moisture, and at sites with more conifers. Soil moisture had a positive effect, especially on the moss in the last year 2018, when the growing season was exceptionally hot and dry. The lichen was mostly affected by gastropod grazing. Recolonization of other plants was also faster at warmer and moister sites. The results indicate that competition, herbivory, shading leaf litter and water scarcity might be more important than the direct effects of temperature for performance at the species' warm range margin. Synthesis. In a transplant experiment with three boreal understorey species, we did not find signs of direct temperature limitation towards the south. Forest microrefugia, that is habitats where these species could persist regional warming, may instead be sites with fewer competitors and enemies, and with sufficient moisture and more conifers in the overstorey. Royal Swedish Academy of Sciences 2014-00530

Published

2021

23. Drivers of demography: past challenges and a promise for a changed future

Author

Eric S. Menges, Geoffrey S. Cook, Pedro F. Quintana-Ascencio, Michelle E. Afkhami, and Johan Ehrlén

Subjects

History, Development economics

Abstract

There is an urgent need to understand how populations and metapopulations respond to shifts in the environment to mitigate the consequences of human actions and global change. Identifying environmental variables/factors affecting population dynamics and the nature of their impacts is fundamental to improve projections and predictions. This chapter examines how environmental drivers, both continuous (stress) and episodic (disturbance), are incorporated in demographic modelling across many types of organisms and environments, using both observational and experimental approaches to characterise drivers. It critically summarises examples of the main approaches and identifies major accomplishments, challenges, and limitations. The chapter points to promising approaches and possible future developments. In the initial sections, models in closed systems without migration among populations are considered. The chapter then focuses on metapopulation models, emphasising the importance of understanding drivers affecting migration and differential extinction among populations. Finally, it concludes with a discussion of some important and general problems associated with assessing how population dynamics may be affected by environmental drivers that are dynamic, nonlinear, and with indirect and/or interacting effects with other drivers..

Published

2021

24. Sex expression and genotypic sex ratio vary with region and environment in the wetland moss Drepanocladus lycopodioides

Author

Lars Hedenäs, Irene Bisang, and Johan Ehrlén

Subjects

geography, geography.geographical_feature_category, biology, Genotypic Sex, Biodiversity, Zoology, Wetland, Plant Science, biology.organism_classification, Moss, Meiosis, Bryophyte, Drepanocladus lycopodioides, Ecology, Evolution, Behavior and Systematics, Sex ratio

Abstract

Sex ratio variation is common among organisms with separate sexes. In bryophytes, sex chromosome segregation at meiosis suggests a balanced progeny sex ratio. However, most bryophyte populations exhibit female-biased phenotypic sex ratios based on the presence of reproductive structures on gametophytes. Many bryophyte populations do not form sexual organs, and genotypic sex ratio variation in such populations is mostly unknown. We tested sex expression, and phenotypic and genotypic sex ratios against environmental parameters in natural populations of the unisexual wetland moss Drepanocladus lycopodiodes at 11 sites in each of three regions in southern Sweden. We identified sex in 660 individual ramets, based on sexual structures, when present, or with a specifically designed molecular marker, when absent. All regions exhibited a female bias in phenotypic and genotypic sex ratios. Sex ratio biases and sex expression differed between regions. Sex ratios were less female-biased in larger patches. Wetter patches exhibited a stronger female bias in genotypic sex ratio and lower sex expression. This is the first evidence of environmental effects on genotypic sex ratio in mosses. A higher frequency of females in wet patches could be due to higher female resource demands for sporophyte production or higher male sensitivity to wetness. A higher incidence of females than males in moister sites aligns with female flowering plants, but differs from reproductive bryophytes in drier environments. Taken together with previous results, our data indicate that sex ratio variation and its drivers differ among species, their life histories and environments.

Published

2019

25. Plant–animal interactions mediate climatic effects on selection on flowering time

Author

Alicia Valdés and Johan Ehrlén

Subjects

Time Factors, biology, Ecology, Phenology, Climate, Population Dynamics, fungi, Lathyrus vernus, food and beverages, Plant physiology, Vertebrate, Flowers, biology.organism_classification, Flowering time, Seed predation, biology.animal, Grazing, Animals, Humans, Pollination, Ecosystem, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm)

Abstract

Selection on flowering time in plants is often mediated by multiple agents, including climatic conditions and the intensity of mutualistic and antagonistic interactions with animals. These selective agents can have both direct and indirect effects. For example, climate might not only influence phenotypic selection on flowering time directly by affecting plant physiology, but it can also alter selection indirectly by modifying the seasonal activity and relative timing of animals interacting with plants. We used 21 years of data to identify the drivers of selection on flowering time in the perennial herb Lathyrus vernus, and to examine if antagonistic plant-animal interactions mediate effects of climate on selection. We examined the fitness consequences of vertebrate grazing and pre-dispersal seed predation, and how these effects varied among years and among individuals within years. Although both antagonistic plant-animal interactions had important negative effects on plant fitness, only grazing intensity was consistently related to plant phenology, being higher in early-flowering individuals. Spring temperature influenced the intensity of both plant-animal interactions, as well as the covariance between seed predation and plant phenology. However, only differences in grazing intensity among years were associated with differences in selection on flowering time; the strength of selection for early flowering being stronger in years with lower mean intensity of grazing. Our results illustrate how climatic conditions can influence plant-animal interactions that are important selective agents for plant traits. A broader implication of our findings is that both ecological and evolutionary responses to climatic changes might be indirect, and largely mediated by species interactions.

Published

2021

26. Author response for 'Warm range margin of boreal bryophytes and lichens not directly limited by temperatures'

Author

Miska Luoto, Sonia Merinero, Eric Meineri, Johan Ehrlén, Kristoffer Hylander, Caroline Greiser, and Benny Willman

Subjects

Boreal, Margin (machine learning), Range (biology), Environmental science, Physical geography, Lichen

Published

2021

27. Author response for 'PHENOTYPIC PLASTICITY MASKS RANGE‐WIDE GENETIC DIFFERENTIATION FOR VEGETATIVE BUT NOT REPRODUCTIVE TRAITS IN A SHORT‐LIVED PLANT'

Author

Aveliina Helm, Olav Skarpaas, Judit Bódis, Christina M. Caruso, Anna-Liisa Laine, Anna Mária Csergő, María B. García, Satu Ramula, Michele Lonati, Matthew Coghill, Meelis Pärtel, Astrid Wingler, Richard P. Duncan, Jesús Villellas, Ayco J. M. Tack, Deborah A. Roach, Alain Finn, Sergi Munné-Bosch, Lauri Laanisto, Paloma Nuche, Benedicte Bachelot, Anna Roeder, Elizabeth M. Wandrag, Pil U. Rasmussen, Dylan Z. Childs, William K. Petry, Bret D. Elderd, Aldo Compagnoni, R. Groenteman, Liv Norunn Hamre, Roberto Salguero-Gómez, Simone Ravetto Enri, Peter A. Vesk, Aryana Ferguson, Ruth Kelly, Gregory E. Vose, Siri Lie Olsen, Annabel L. Smith, Joachim Töpper, Jane A. Catford, John M. Dwyer, Zuzana Münzbergová, Emily Griffoul, Yvonne M. Buckley, Adrian Oprea, Anna Bucharova, Glenda M. Wardle, Lauchlan H. Fraser, Elizabeth E. Crone, Johan Ehrlén, Cheryl B. Schultz, and Christiane Roscher

Subjects

Phenotypic plasticity, Evolutionary biology, Range (biology), Biology, Genetic differentiation

Published

2021

28. Pathogen infection influences the relationship between spring and autumn phenology at the seedling and leaf level

Author

Jessie, Mutz, Ryan, McClory, Laura J A, van Dijk, Johan, Ehrlén, and Ayco J M, Tack

Subjects

Plant Leaves, Quercus, Seedlings, Fungi, Seasons, Plant Diseases, Trees

Abstract

Seasonal life history events are often interdependent, but we know relatively little about how the relationship between different events is influenced by the abiotic and biotic environment. Such knowledge is important for predicting the immediate and evolutionary phenological response of populations to changing conditions. We manipulated germination timing and shade in a multi-factorial experiment to investigate the relationship between spring and autumn phenology in seedlings of the pedunculate oak, Quercus robur, and whether this relationship was mediated by natural colonization of leaves by specialist fungal pathogens (i.e., the oak powdery mildew complex). Each week delay in germination corresponded to about 2 days delay in autumn leaf senescence, and heavily shaded seedlings senesced 5-8 days later than seedlings in light shade or full sun. Within seedlings, leaves on primary-growth shoots senesced later than those on secondary-growth shoots in some treatments. Path analyses demonstrated that germination timing and shade affected autumn phenology both directly and indirectly via pathogen load, though the specific pattern differed among and within seedlings. Pathogen load increased with later germination and greater shade. Greater pathogen load was in turn associated with later senescence for seedlings, but with earlier senescence for individual leaves. Our findings show that relationships between seasonal events can be partly mediated by the biotic environment and suggest that these relationships may differ between the plant and leaf level. The influence of biotic interactions on phenological correlations across scales has implications for understanding phenotypic variation in phenology and for predicting how populations will respond to climatic perturbation.

Published

2021

29. Genetic differentiation can be predicted from observational data for reproductive but not vegetative traits in a widespread short-lived plant

Author

María B. García, Anna-Liisa Laine, Ayco J. M. Tack, Olav Skarpaas, Judit Bódis, Jane A. Catford, Zuzana Münzbergová, John M. Dwyer, Joachim Töpper, Simone Ravetto Enri, R. Groenteman, William K. Petry, Benedicte Bachelot, Yvonne M. Buckley, Sergi Munné-Bosch, Lauri Laanisto, Elizabeth M. Wandrag, Ruth Kelly, Anna Roeder, Astrid Wingler, Matthew Coghill, Richard P. Duncan, Alain Finn, Jesús Villellas, Aryana Ferguson, Deborah A. Roach, Pil U. Rasmussen, Paloma Nuche, Anna Mária Csergő, Bret D. Elderd, Aldo Compagnoni, Adrian Oprea, Michele Lonati, Peter A. Vesk, Satu Ramula, Dylan Z. Childs, Roberto Salguero-Gómez, Siri Lie Olsen, Emily Griffoul, Aveliina Helm, Gregory E. Vose, Meelis Pärtel, Annabel L. Smith, Glenda M. Wardle, Liv Norunn Hamre, Anna Bucharova, Cheryl B. Schultz, Lauchlan H. Fraser, Christiane Roscher, Elizabeth E. Crone, Johan Ehrlén, and Christina M. Caruso

Subjects

Biomass (ecology), Phenotypic plasticity, education.field_of_study, Evolutionary biology, Population, Trait, Observational study, Biology, education, Genetic differentiation

Abstract

Phenotypic plasticity can mask population genetic differentiation, reducing the predictability of trait-environment relationships. In short-lived plants, reproductive traits may be more genetically determined due to their direct impact on fitness, whereas vegetative traits may show higher plasticity to buffer short-term perturbations. Combining a multi-treatment greenhouse experiment with global field observations for the short-lived Plantago lanceolata, we 1) disentangled the genetic and plastic responses of functional traits to a set of environmental drivers and 2) assessed the utility of trait-environment relationshisps inferred from observational data for predicting genetic differentiation. Reproductive traits showed distinct genetic differentiation that was highly predictable from observational data, but only when correcting traits for differences in their (labile) biomass component. Vegetative traits showed higher plasticity and contrasting genetic and plastic responses, leading to unpredictable trait patterns. Our study suggests that genetic differentiation may be inferred from observational data only for the traits most closely related with fitness.

Published

2021

30. Phenotypic plasticity masks range- wide genetic differentiation for vegetative but not reproductive traits in a short- lived plant

Author

Jane A. Catford, Cheryl B. Schultz, Zuzana Münzbergová, Christiane Roscher, Yvonne M. Buckley, Anna Mária Csergő, Liv Norunn Hamre, Lauchlan H. Fraser, Richard P. Duncan, Jesús Villellas, Anna-Liisa Laine, Gregory E. Vose, John M. Dwyer, Christina M. Caruso, Annabel L. Smith, R. Groenteman, Deborah A. Roach, Dylan Z. Childs, Michele Lonati, María B. García, Adrian Oprea, Aveliina Helm, Paloma Nuche, Peter A. Vesk, Elizabeth E. Crone, Benedicte Bachelot, Ayco J. M. Tack, Simone Ravetto Enri, Matthew Coghill, Anna Roeder, Siri Lie Olsen, Emily Griffoul, Johan Ehrlén, Judit Bódis, Astrid Wingler, Meelis Pärtel, William K. Petry, Sergi Munné-Bosch, Lauri Laanisto, Ruth Kelly, Elizabeth M. Wandrag, Joachim Töpper, Alain Finn, Roberto Salguero-Gómez, Aryana Ferguson, Olav Skarpaas, Pil U. Rasmussen, Bret D. Elderd, Aldo Compagnoni, Satu Ramula, Anna Bucharova, and Glenda M. Wardle

Subjects

0106 biological sciences, root:shoot ratio, Range (biology), fecundity, genotype by environment interaction, Biology, 010603 evolutionary biology, 01 natural sciences, Intraspecific competition, observational datasets, biomass, common garden experiment, countergradient variation, intraspecific trait variation, specific leaf area, widespread species, VDP::Samfunnsvitenskap: 200::Urbanisme og fysisk planlegging: 230::Landskapsplanlegging: 236, Biomass, Gene–environment interaction, Plantago, Ecology, Evolution, Behavior and Systematics, Phenotypic plasticity, Ecology, Botánica, Masks, 15. Life on land, Fecundity, Adaptation, Physiological, Phenotype, Genética, Evolutionary biology, Trait, Adaptation, 010606 plant biology & botany

Abstract

Genetic differentiation and phenotypic plasticity jointly shape intraspecific trait variation, but their roles differ among traits. In short- lived plants, reproductive traits may be more genetically determined due to their impact on fitness, whereas vegetative traits may show higher plasticity to buffer short- term perturbations. Combining a multi- treatment greenhouse experiment with observational field data throughout the range of a widespread short- lived herb, Plantago lanceolata, we (1) disentangled genetic and plastic responses of functional traits to a set of environmental drivers and (2) assessed how genetic differentiation and plasticity shape observational trait– environment relationships. Reproductive traits showed distinct genetic differentiation that largely determined observational patterns, but only when correcting traits for differences in biomass. Vegetative traits showed higher plasticity and opposite genetic and plastic responses, masking the genetic component underlying field- observed trait variation. Our study suggests that genetic differentiation may be inferred from observational data only for the traits most closely related to fitness.

Published

2021

31. The impact of microclimate and soil on the ecology and evolution of an arctic plant

Author

Bryndís Marteinsdóttir, Niklas Jan Wickander, Ayco J. M. Tack, Johan Ehrlén, and Pil U. Rasmussen

Subjects

biology, Arctic, Ecology, Microclimate, Environmental science, Climate change, Context (language use), Evolutionary ecology, Vegetation, biology.organism_classification, Local adaptation, Bistorta vivipara

Abstract

The arctic and alpine regions are predicted to experience one 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 temperature gradients naturally 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 to examine the impact of temperature on the response of arctic-alpine plants to increasing temperatures. To test the ecological and evolutionary response of the circumpolar alpine bistort (Bistorta vivipara) to temperature, we collected plant material and soil from areas with low, intermediate, and high soil temperatures and grew them in all combinations at three different temperatures. 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 B. vivipara, 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.

Published

2020

32. Drivers of large-scale spatial demographic variation in a perennial plant

Author

Hendrik de Buhr, Ditte M. Christiansen, Owen R. Jones, Johan P. Dahlgren, Gesa Römer, Sonia Merinero, Johan Ehrlén, Kasper Reitzel, and Kristoffer Hylander

Subjects

Perennial plant, Scale (ratio), perennial herb, Population, spatial variation, Intraspecific competition, plant demography, Abundance (ecology), population dynamics, Population growth, population growth rate, Realized niche width, education, Ecology, Evolution, Behavior and Systematics, education.field_of_study, Ecology, biology, Perennial herb, biology.organism_classification, Variation (linguistics), Geography, environmental drivers, Environmental science, Spatial variability, Actaea spicata, Physical geography, Vital rates, integral projection model

Abstract

To understand how the environment drives spatial variation in population dynamics, we need to assess the effects of a large number of potential drivers on the vital rates (survival, growth and reproduction), and explore these relationships over large geographical areas and long environmental gradients. In this study, we examined the effects of a broad variety of abiotic and biotic environmental factors, including intraspecific density, on the demography of the forest understory herbActaea spicatabetween 2017 and 2019 at 40 sites across Sweden, including the northern range margin of its distribution. We assessed the effect of potential environmental drivers on vital rates using generalized linear mixed models (GLMMs), and then quantified the impact of each important driver on population growth rate (λ) using integral projection models (IPMs). Population dynamics ofA. spicatawere mostly driven by environmental factors affecting survival and growth, such as air humidity, soil depth and forest tree species composition, and thus those drivers jointly determined the realized niche of the species. Soil pH had a strong effect on the flowering probability, while the effect on population growth rate was relatively small. In addition to identifying specific drivers forA. spicata’spopulation dynamics, our study illustrates the impact that spatial variation in environmental conditions can have on λ. Assessing the effects of a broad range of potential drivers, as done in this study, is important not only to quantify the relative importance of different drivers for population dynamics but also to understand species distributions and abundance patterns.

Published

2020

33. Butterfly–host plant synchrony determines patterns of host use across years and regions

Author

Karl Gotthard, Jose A. Navarro-Cano, Diana Posledovich, Johan Ehrlén, Tenna Toftegaard, Christer Wiklund, Swedish Research Council, Fundación Séneca, Navarro-Cano, J. A. [0000-0001-8091-1063], and Navarro-Cano, J. A.

Subjects

0106 biological sciences, Oviposition, Host species use, Biology, 010603 evolutionary biology, 01 natural sciences, Host plants, Herbivory, Species interactions, Ecology, Evolution, Behavior and Systematics, Herbivore, Natural selection, Anthocharis cardamines, Host (biology), Phenology, Ecology, 010604 marine biology & hydrobiology, fungi, food and beverages, biology.organism_classification, Seed predation, Mismatch, Butterfly

Abstract

Variation in the degree of synchrony among host plants and herbivores can disrupt or intensify species interactions, alter the strength of natural selection on traits associated with phenological timing, and drive novel host plant associations. We used field observations from three regions during four seasons to examine how timing of the butterfly herbivore Anthocharis cardamines relative to six host plant species (Arabis hirsuta, Cardamine pratensis, Arabis glabra, Arabidopsis thaliana, Thlaspi caerulescens and Capsella bursa-pastoris) influenced host species use and the choice of host plant individuals within populations. Butterflies laid a larger fraction of their eggs on species that were closer to the butterfly's preferred stage of development than on other host species. Within host plant populations, butterflies showed a stronger preference for individuals with a late phenology when plants within the population were on average more developed at the time of butterfly flight. Our results suggest that changes in synchrony between herbivores and their host plants are associated with changes in both host species use and the choice of host plant individuals differing in phenology within populations. This is likely to be an important mechanism generating variation in interaction intensities and trait selection in the wild, and therefore also relevant for understanding how anthropogenic induced changes, such as global warming, will influence natural communities., This study was funded by the Swedish Research Council (JE) and Séneca Foundation (postdoctoral grant 12337/PD/09 to JANC) for funding.

Published

2018

34. Global shifts in the phenological synchrony of species interactions over recent decades

Author

Steve E. Travers, Andrew Gelman, Heather M. Kharouba, Jenica M. Allen, Elizabeth M. Wolkovich, Kjell Bolmgren, and Johan Ehrlén

Subjects

0106 biological sciences, Food Chain, Multidisciplinary, 010504 meteorology & atmospheric sciences, Phenology, Ecology, Climate Change, Population Dynamics, Global warming, Climate change, Biological Sciences, Biology, 010603 evolutionary biology, 01 natural sciences, Animals, Ecosystem, Terrestrial ecosystem, Seasons, Biological sciences, 0105 earth and related environmental sciences

Abstract

Phenological responses to climate change (e.g., earlier leaf-out or egg hatch date) are now well documented and clearly linked to rising temperatures in recent decades. Such shifts in the phenologies of interacting species may lead to shifts in their synchrony, with cascading community and ecosystem consequences. To date, single-system studies have provided no clear picture, either finding synchrony shifts may be extremely prevalent [Mayor SJ, et al. (2017) Sci Rep 7:1902] or relatively uncommon [Iler AM, et al. (2013) Glob Chang Biol 19:2348–2359], suggesting that shifts toward asynchrony may be infrequent. A meta-analytic approach would provide insights into global trends and how they are linked to climate change. We compared phenological shifts among pairwise species interactions (e.g., predator–prey) using published long-term time-series data of phenological events from aquatic and terrestrial ecosystems across four continents since 1951 to determine whether recent climate change has led to overall shifts in synchrony. We show that the relative timing of key life cycle events of interacting species has changed significantly over the past 35 years. Further, by comparing the period before major climate change (pre-1980s) and after, we show that estimated changes in phenology and synchrony are greater in recent decades. However, there has been no consistent trend in the direction of these changes. Our findings show that there have been shifts in the timing of interacting species in recent decades; the next challenges are to improve our ability to predict the direction of change and understand the full consequences for communities and ecosystems.

Published

2018

35. Direct and plant trait-mediated effects of the local environmental context on butterfly oviposition patterns

Author

Alicia Valdés and Johan Ehrlén

Subjects

0106 biological sciences, Ecology, 010604 marine biology & hydrobiology, fungi, food and beverages, Context (language use), Biology, 010603 evolutionary biology, 01 natural sciences, Environmental variation, Butterfly, Trait, Plant traits, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm)

Abstract

Variation in the intensity of plant-animal interactions over different spatial scales is widespread and might strongly influence fitness and trait selection in plants. Differences in traits among p ...

Published

2018

36. Spring phenology dominates over light availability in affecting seedling performance and plant attack during the growing season

Author

Jessie Mutz, R.W. McClory, L. J. A. van Dijk, Johan Ehrlén, and Ayco J. M. Tack

Subjects

0106 biological sciences, Canopy, Abiotic component, Herbivore, biology, Phenology, fungi, food and beverages, Growing season, Forestry, Understory, Management, Monitoring, Policy and Law, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Agronomy, Seedling, Germination, 010606 plant biology & botany, Nature and Landscape Conservation

Abstract

Climate change can have important effects on plant performance by altering the relationship between spring temperature and other abiotic factors, such as light availability. Higher temperatures can advance plant phenology so that seedling germination takes place when days are shorter, and affect light availability for understory plants by altering the relative timing of seedling germination and canopy closure. To predict the effects of climate-induced changes in phenology and light availability on plant performance and species interactions during the growing season, we need to determine i) how effects of plant phenology on plant performance and the plant-associated community depend on light availability, and ii) to what extent effects of phenology and light availability on plant performance are direct vs. mediated by changes in the plant-associated community. We conducted a multifactorial field experiment to test for the effect of germination timing and light availability on Quercus robur seedling traits and performance, as well as attack by specialist plant pathogens, insects, and small mammals. Germination timing strongly affected seedling performance whereas light availability’s effects were limited. Likewise, germination timing strongly affected herbivore and pathogen attack, whereas light availability and its interaction with germination timing explained a minor part of the variation. Small mammals preferentially attacked later germinating seedlings, which strongly affected plant survival, while insect herbivores and pathogens did not mediate the effect of germination timing and light availability on plant performance. The results showed that the effect of germination timing can have greater influence than light availability on plant performance and plant attack, and that small mammal herbivores can play a larger role than diseases and insect herbivores in mediating the effect of spring phenology on plant performance. Together, these findings advance our understanding of the consequences of climate-induced changes in spring phenology and the abiotic environment on plant performance within a community context.

Published

2021

37. Plant-herbivore synchrony and selection on plant flowering phenology

Author

Johan P. Dahlgren, Elsa Fogelström, Johan Ehrlén, Martin Olofsson, Christer Wiklund, and Diana Posledovich

Subjects

0106 biological sciences, Natural selection, Population, 010603 evolutionary biology, 01 natural sciences, Animals, Herbivory, education, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm), Herbivore, education.field_of_study, biology, Anthocharis cardamines, Phenology, Ecology, Reproduction, 010604 marine biology & hydrobiology, Herbivore preference, fungi, food and beverages, Cardamine pratensis, Plants, biology.organism_classification, Trophic interaction, Reaction norm, Phenotype, Butterfly, Cardamine, Butterflies

Abstract

Temporal variation in natural selection has profound effects on the evolutionary trajectories of populations. One potential source of variation in selection is that differences in thermal reaction norms and temperature influence the relative phenology of interacting species. We manipulated the phenology of the butterfly herbivore Anthocharis cardamines relative to genetically identical populations of its host plant, Cardamine pratensis, and examined the effects on butterfly preferences and selection acting on the host plant. We found that butterflies preferred plants at an intermediate flowering stage, regardless of the timing of butterfly flight relative to flowering onset of the population. Consequently, the probability that plant genotypes differing in timing of flowering should experience a butterfly attack depended strongly on relative phenology. These results suggest that differences in spring temperature influence the direction of herbivore-mediated selection on flowering phenology, and that climatic conditions can influence natural selection also when phenotypic preferences remain constant.

Published

2017

38. Biotic and anthropogenic forces rival climatic/abiotic factors in determining global plant population growth and fitness

Author

Johan P. Dahlgren, Allison M. Louthan, William F. Morris, Alexander K Loomis, and Johan Ehrlén

Subjects

0106 biological sciences, Population, Biome, Biodiversity, Climate change, 010603 evolutionary biology, 01 natural sciences, Ecosystem services, Population growth, population growth rate, education, 2. Zero hunger, Abiotic component, species interactions, education.field_of_study, Multidisciplinary, Ecology, environmental driver, 010604 marine biology & hydrobiology, fungi, food and beverages, Biological Sciences, 15. Life on land, anthropogenic impacts, climate change, Disturbance (ecology), 13. Climate action, Environmental science

Abstract

Significance Knowing which of multiple environmental factors (climate, other species, humans, etc.) most strongly affect wild plants and animals could focus our attention on the future environmental changes most likely to influence biodiversity. However, we find that abiotic, biotic, and human influences on plant populations are of similar strengths, for different kinds of plants and in multiple locations and environments. The effects of these factors on plant evolution are also likely to be similar. Thus, there is unlikely to be a shortcut to considering all of these factors when predicting the future ecological and evolutionary responses of species and of biodiversity to environmental changes., Multiple, simultaneous environmental changes, in climatic/abiotic factors, interacting species, and direct human influences, are impacting natural populations and thus biodiversity, ecosystem services, and evolutionary trajectories. Determining whether the magnitudes of the population impacts of abiotic, biotic, and anthropogenic drivers differ, accounting for their direct effects and effects mediated through other drivers, would allow us to better predict population fates and design mitigation strategies. We compiled 644 paired values of the population growth rate (λ) from high and low levels of an identified driver from demographic studies of terrestrial plants. Among abiotic drivers, natural disturbance (not climate), and among biotic drivers, interactions with neighboring plants had the strongest effects on λ. However, when drivers were combined into the 3 main types, their average effects on λ did not differ. For the subset of studies that measured both the average and variability of the driver, λ was marginally more sensitive to 1 SD of change in abiotic drivers relative to biotic drivers, but sensitivity to biotic drivers was still substantial. Similar impact magnitudes for abiotic/biotic/anthropogenic drivers hold for plants of different growth forms, for different latitudinal zones, and for biomes characterized by harsher or milder abiotic conditions, suggesting that all 3 drivers have equivalent impacts across a variety of contexts. Thus, the best available information about the integrated effects of drivers on all demographic rates provides no justification for ignoring drivers of any of these 3 types when projecting ecological and evolutionary responses of populations and of biodiversity to environmental changes.

Published

2020

39. Climate limitation at the cold edge: contrasting perspectives from species distribution modelling and a transplant experiment

Author

Johan Ehrlén, Eric Meineri, Miska Luoto, Caroline Greiser, Kristoffer Hylander, Stockholm University, Institut méditerranéen de biodiversité et d'écologie marine et continentale (IMBE), Avignon Université (AU)-Aix Marseille Université (AMU)-Institut de recherche pour le développement [IRD] : UMR237-Centre National de la Recherche Scientifique (CNRS), Thule Institute, University of Oulu, Helsinki Institute of Sustainability Science (HELSUS), and Department of Geosciences and Geography

Subjects

0106 biological sciences, demography, NICHES, PREDICTION, Range (biology), [SDE.MCG]Environmental Sciences/Global Changes, Species distribution, DIVERSITY, Microclimate, Climate change, 010603 evolutionary biology, 01 natural sciences, PINE, COLONIZATION, soil, PLANTS, boreal forest, Temporal scales, Ecology, Evolution, Behavior and Systematics, RANGE, Ecology, 010604 marine biology & hydrobiology, Understory, 15. Life on land, MICROCLIMATES, Soil quality, range margin, Environmental niche modelling, 1181 Ecology, evolutionary biology, canopy cover, Environmental science, ABUNDANCE, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, microclimate

Abstract

International audience; The role of climate in determining range margins is often studied using species distribution models (SDMs), which are easily applied but have well-known limitations, e.g. due to their correlative nature and colonization and extinction time lags. Transplant experiments can give more direct information on environmental effects, but often cover small spatial and temporal scales. We simultaneously applied a SDM using high-resolution spatial predictors and an integral projection (demographic) model based on a transplant experiment at 58 sites to examine the effects of microclimate, light and soil conditions on the distribution and performance of a forest herb, Lathyrus vernus, at its cold range margin in central Sweden. In the SDM, occurrences were strongly associated with warmer climates. In contrast, only weak effects of climate were detected in the transplant experiment, whereas effects of soil conditions and light dominated. The higher contribution of climate in the SDM is likely a result from its correlation with soil quality, forest type and potentially historic land use, which were unaccounted for in the model. Predicted habitat suitability and population growth rate, yielded by the two approaches, were not correlated across the transplant sites. We argue that the ranking of site habitat suitability is probably more reliable in the transplant experiment than in the SDM because predictors in the former better describe understory conditions, but that ranking might vary among years, e.g. due to differences in climate. Our results suggest that L. vernus is limited by soil and light rather than directly by climate at its northern range edge, where conifers dominate forests and create suboptimal conditions of soil and canopy-penetrating light. A general implication of our study is that to better understand how climate change influences range dynamics, we should not only strive to improve existing approaches but also to use multiple approaches in concert.

Published

2020

40. Spring phenology dominates over shade in affecting seedling performance and plant attack during the growing season

Author

Ayco J. M. Tack, Jessie Mutz, L. J. A. van Dijk, Johan Ehrlén, and R. W. McClory

Subjects

Abiotic component, Quercus robur, Herbivore, biology, Seedling, Phenology, Ecology, Field experiment, fungi, food and beverages, Growing season, Context (language use), biology.organism_classification

Abstract

O_LIClimate change is affecting both the abiotic environment and the seasonal timing of life history events, with potentially major consequences for plant performance and plant-associated food webs. Despite this, we lack insights into how effects of plant phenology on plant performance and food webs depend on environmental conditions, and to what extent effects of phenology and the environment on plant performance are direct vs. mediated by changes in the plant-associated community. C_LIO_LIWe conducted a multifactorial field experiment to test for the effect of spring phenology and shade on Quercus robur seedling traits and performance, as well as attacks by specialist plant pathogens, insects and small mammals. C_LIO_LISpring phenology strongly affected seedling performance whereas shade only affected leaf thickness and chlorophyll. Likewise, spring phenology strongly affected herbivore and pathogen attack, whereas shade and its interaction with spring phenology only explained a minor part of the variation. Small mammals preferentially attacked later phenology seedlings, which strongly affected plant survival, while insect herbivores and pathogens did not mediate the effect of spring phenology and shade on plant performance. C_LIO_LISynthesis: This study highlights that the effect of spring phenology outweighs the effect of environmental context on plant performance and plant attack during the growing season. Interestingly, small mammal herbivores, and not diseases and insect herbivores, may play a key role in mediating the effect of spring phenology on plant performance. Together, these findings advance our understanding of the consequences of climate-induced changes in spring phenology and the abiotic environment on plant performance within a community context. C_LI

Published

2020

41. Correlations between plant climate optima across different spatial scales

Author

Ditte M. Christiansen, C. Johan Dahlberg, Johan Ehrlén, Kristoffer Hylander, Eric Meineri, Stockholm University, Institut méditerranéen de biodiversité et d'écologie marine et continentale (IMBE), Avignon Université (AU)-Aix Marseille Université (AMU)-Institut de recherche pour le développement [IRD] : UMR237-Centre National de la Recherche Scientifique (CNRS), and Centre National de la Recherche Scientifique (CNRS)-Institut de recherche pour le développement [IRD] : UMR237-Aix Marseille Université (AMU)-Avignon Université (AU)

Subjects

0106 biological sciences, 0301 basic medicine, [SDE.MCG]Environmental Sciences/Global Changes, Niche, Distribution (economics), Plant Science, 01 natural sciences, 03 medical and health sciences, Abundance (ecology), Ecology, Evolution, Behavior and Systematics, ComputingMilieux_MISCELLANEOUS, Ecology, business.industry, Growing degree-day, 15. Life on land, Regression, 030104 developmental biology, Geography, Habitat, 13. Climate action, Climate model, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, Scale (map), business, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

Identifying the factors determining the abundance and distribution of species is a fundamental question in ecology. One key issue is how similar the factors determining species’ distributions across spatial scales are (here we focus especially on spatial extents). If the factors are similar across extents, then the large scale distribution pattern of a species may provide information about its local habitat requirements, and vice versa. We assessed the relationships between landscape and national optima as well as landscape and continental optima for growing degree days, maximum temperature and minimum temperature for 96 bryophytes and 50 vascular plants. For this set of species, we derived landscape optima from abundance weighted temperature data using species inventories in central Sweden and a fine-grained temperature model (50 m), national optima from niche centroid modelling based on GBIF data from Sweden and the same fine-grained climate model, and continental optima using the same method as for the national optima but from GBIF data from Europe and Worldclim temperatures (c. 1000 m). The landscape optima of all species were positively correlated with national as well as continental optima for maximum temperature (r = 0.45 and 0.46, respectively), weakly so for growing degree days (r = 0.30 and r = 0.28), but sometimes absent for minimum temperature (r = 0.26 and r = 0.04). The regression slopes of national or continental optima on local optima did not differ between vascular plants and bryophytes for GDD and Tmax. However, the relationship between the optima of Tmin differed between groups, being positive in vascular plants but absent in bryophytes. Our results suggest that positive correlations between optima at different spatial scales are present for some climatic variables but not for others. Moreover, our results for vascular plants and bryophytes suggest that correlations might differ between organism groups and depend on the ecology of the focal organisms. This implies that it is not possible to routinely up- or downscale distribution patterns based on environmental correlations, since drivers of distribution patterns might differ across spatial extents.

Published

2020

42. Global gene flow releases invasive plants from environmental constraints on genetic diversity

Author

William K. Petry, Joslin L. Moore, R. Groenteman, Anna Roeder, Anna Mária Csergő, Aveliina Helm, Pil U. Rasmussen, Elizabeth M. Wandrag, Siri Lie Olsen, Judit Bódis, Bret D. Elderd, John M. Dwyer, Astrid Wingler, Christina M. Caruso, María B. García, Simone P. Blomberg, Satu Ramula, Simone Ravetto Enri, Ayco J. M. Tack, Annabel L. Smith, Maude E.A. Baudraz, Ruth Kelly, Marjo Saastamoinen, Jane A. Catford, Roberto Salguero-Gómez, Trevor R. Hodkinson, Dylan Z. Childs, Anna-Liisa Laine, Melanie Morales, Liv Norunn Hamre, Michele Lonati, Francis Q. Brearley, Gregory E. Vose, Glenda M. Wardle, Alain Finn, Sergi Munné-Bosch, Lauri Laanisto, Ben Gooden, Anna Bucharova, Elizabeth E. Crone, Johan Ehrlén, Christiane Roscher, Yvonne M. Buckley, Meelis Pärtel, Richard P. Duncan, Jesús Villellas, Deborah A. Roach, Joachim Töpper, Science Foundation Ireland, European Research Council, European Commission, Generalitat de Catalunya, Ministerio de Economía y Competitividad (España), Ministry of Education and Research (Estonia), Ministry of Business, Innovation, and Employment (New Zealand), and Academy of Finland

Subjects

Gene Flow, 0106 biological sciences, Plant invasion, Population genetics, Range (biology), Biology, 010603 evolutionary biology, 01 natural sciences, Invasive species, 03 medical and health sciences, Geographical distance, Adaptation, Plantago, Global change, Phylogeny, Demography, 030304 developmental biology, 0303 health sciences, Genetic diversity, Multidisciplinary, Ecology, Genetic Variation, Biological Sciences, 15. Life on land, Genetic structure, Biological dispersal, Introduced Species

Abstract

Significance We found that long-distance dispersal and repeated introductions by humans have shaped adaptive potential in a globally distributed invasive species. Some plant species, therefore, do not need strong demographic changes to overcome environmental constraints that exist in the native range; simply mixing genetic stock from multiple populations can provide an adaptive advantage. This work highlights the value of preventing future introduction events for problematic invasive species, even if the species already exists in an area., When plants establish outside their native range, their ability to adapt to the new environment is influenced by both demography and dispersal. However, the relative importance of these two factors is poorly understood. To quantify the influence of demography and dispersal on patterns of genetic diversity underlying adaptation, we used data from a globally distributed demographic research network comprising 35 native and 18 nonnative populations of Plantago lanceolata. Species-specific simulation experiments showed that dispersal would dilute demographic influences on genetic diversity at local scales. Populations in the native European range had strong spatial genetic structure associated with geographic distance and precipitation seasonality. In contrast, nonnative populations had weaker spatial genetic structure that was not associated with environmental gradients but with higher within-population genetic diversity. Our findings show that dispersal caused by repeated, long-distance, human-mediated introductions has allowed invasive plant populations to overcome environmental constraints on genetic diversity, even without strong demographic changes. The impact of invasive plants may, therefore, increase with repeated introductions, highlighting the need to constrain future introductions of species even if they already exist in an area.

Published

2020

43. Sex and the cost of reproduction through the life course of an extremely long-lived herb

Author

Johan P. Dahlgren, Johan Ehrlén, María B. García, and Danielle A. Sherman

Subjects

Male, 0106 biological sciences, food.ingredient, Demographic senescence, media_common.quotation_subject, Flowers, Biology, 010603 evolutionary biology, 01 natural sciences, Reproductive value, Life history theory, Reproductive senescence, food, Life history, Ecology, Evolution, Behavior and Systematics, media_common, Reproduction, 010604 marine biology & hydrobiology, food and beverages, Ageing, Herb, Reproductive effort, Seeds, Life course approach, Female, Vital rates, Demography

Abstract

Despite being central concepts for life history theory, little is known about how reproductive effort and costs vary with individual age once plants have started to reproduce. We conducted a 5-year field study and estimated age-dependent reproductive effort for both sexes in the extraordinarily long-lived dioecious plant Borderea pyrenaica. We also evaluated costs of reproduction on vital rates for male and female plants, both by examining effects of differences in individual reproductive effort under natural conditions, and by conducting a flower removal experiment, aimed at decreasing reproductive effort. Reproductive effort was fairly constant and independent of age for males, which may reflect a strategy of adjusting overall reproductive output by spreading reproduction over the life course. Females had a higher total effort, which first increased and then decreased with age. The latter may be a response to an increasing reproductive value—an inverse of a terminal investment—or a sign of reproductive senescence due to an age-related physiological decline. Seed production was lower in plants with higher previous reproductive effort and this effect increased with age. We found no evidence for costs of reproduction on other vital rates for either sex. Experimental flower removal only resulted in progressively more negative effects on flower production in older male plants, whereas female vital rates were unaffected. Overall, this study demonstrates that not only sex, but also age influences resource allocation trade-offs and, thus, plant life history evolution.

Published

2019

44. Climate change in grasslands – demography and population dynamics

Author

Johan Ehrlén

Subjects

education.field_of_study, Geography, Ecology, Population, Climate change, education

Published

2019

45. Intraspecific variation influences performance of moss transplants along microclimate gradients

Author

Sonia, Merinero, C Johan, Dahlberg, Johan, Ehrlén, and Kristoffer, Hylander

Subjects

Sweden, bryophyte, Hylocomiastrum umbratum, Climate Change, Bryophyta, Microclimate, Articles, Forests, Article, microclimate gradient, vital rates, intraspecific variation, common garden experiment, transplantation experiment, local adaptation, overall performance, latitudinal clines

Abstract

Identifying the environmental drivers of population dynamics is crucial to predict changes in species abundances and distributions under climate change. Populations of the same species might differ in their responses as a result of intraspecific variation. Yet the importance of such differences remains largely unexplored. We examined the responses of latitudinally distant populations of the forest moss Hylocomiastrum umbratum along microclimate gradients in Sweden. We transplanted moss mats from southern and northern populations to 30 sites with contrasting microclimates (i.e., replicated field common gardens) within a forest landscape, and recorded growth and survival of individual shoots over 3 yr. To evaluate the importance of intraspecific variation in responses to environmental factors, we assessed effects of the interactions between population origin and microclimate drivers on growth and survival. Effects on overall performance of transplanted populations were estimated using the product of survival and growth. We found differences between southern and northern populations in the response to summer temperature and snowmelt date in one of three yearly transitions. In this year, southern populations performed better in warm, southern‐like conditions than in cold, northern‐like conditions; and the reverse pattern was true for northern populations. Survival of all populations decreased with evaporation, consistent with the high hydric demands and poikilohydric nature of mosses. Our results are consistent with population adaptation to local climate, and suggest that intraspecific variation among populations can have important effects on the response of species to microclimate drivers. These findings highlight the need to account for differential responses in predictions of species abundance and distribution under climate change.

Published

2019

46. Caterpillar seed predators mediate shifts in selection on flowering phenology in their host plant

Author

Johan Ehrlén and Alicia Valdés

Subjects

0106 biological sciences, Phengaris alcon, Flowers, 010603 evolutionary biology, 01 natural sciences, Myrmica, Animals, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm), biology, Ants, Phenology, Ecology, Host (biology), Reproduction, fungi, food and beverages, General Medicine, Plants, biology.organism_classification, Myrmecophily, Gentiana pneumonanthe, Seeds, Butterfly, Butterflies, 010606 plant biology & botany

Abstract

Variation in selection among populations and years has important implications for evolutionary trajectories of populations. Yet, the agents of selection causing this variation have rarely been identified. Selection on the time of reproduction within a season in plants might differ both among populations and among years, and selection can be mediated by both mutualists and antagonists. We investigated if differences in the direction of phenotypic selection on flowering phenology among 20 populations of Gentiana pneumonanthe during 2 yr were related to the presence of the butterfly seed predator Phengaris alcon, and if butterfly incidence was associated with the abundance of the butterfly's second host, Myrmica ants. In plant populations without the butterfly, phenotypic selection favored earlier flowering. In populations where the butterfly was present, caterpillars preferentially attacked early-flowering individuals, shifting the direction of selection to favoring later flowering. Butterfly incidence in plant populations increased with ant abundance. Our results demonstrate that antagonistic interactions can shift the direction of selection on flowering phenology, and suggest that such shifts might be associated with differences in the community context.

Published

2017

47. Phenological matching rather than genetic variation in host preference underlies geographical variation in host plants used by orange tip butterflies

Author

Olof Leimar, Christer Wiklund, Martin Olofsson, Karl Gotthard, Sandra Stålhandske, and Johan Ehrlén

Subjects

0106 biological sciences, Ecology, Phenology, Host (biology), 010604 marine biology & hydrobiology, media_common.quotation_subject, fungi, Orange (colour), Alliaria petiolata, Insect, Biology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Anthocharis cardamines, Genetic variation, Ecology, Evolution, Behavior and Systematics, Local adaptation, media_common

Abstract

An insect species that shows variation in host species association across its geographical range may do so either because of local adaptation in host plant preference of the insect, or through envi ...

Published

2016

48. Forest succession and population viability of grassland plants: long repayment of extinction debt in Primula veris

Author

Johan P. Dahlgren, Johan Ehrlén, María B. García, Roosa Leimu, Kimmo Syrjänen, and Kari Lehtilä

Subjects

0106 biological sciences, Population Dynamics, Population, Ecological succession, Forests, Biology, Models, Biological, 010603 evolutionary biology, 01 natural sciences, Abundance (ecology), education, Finland, Ecology, Evolution, Behavior and Systematics, Sweden, education.field_of_study, Extinction, Ecology, 010604 marine biology & hydrobiology, biology.organism_classification, Grassland, humanities, Primula, Disturbance (ecology), Habitat, Extinction debt

Abstract

Time lags in responses of organisms to deteriorating environmental conditions delay population declines and extinctions. We examined how local processes at the population level contribute to extinction debt, and how cycles of habitat deterioration and recovery may delay extinction. We carried out a demographic analysis of the fate of the grassland perennial Primula veris after the cessation of grassland management, where we used either a unidirectional succession model for forest habitat or a rotation model with a period of forest growth followed by a clear-cut and a new successional cycle. The simulations indicated that P. veris populations may have an extinction time of decades to centuries after a detrimental management change. A survey of the current incidence and abundance of P. veris in sites with different histories of afforestation confirmed the simulation results of low extinction rates. P. veris had reduced incidence and abundance only at sites with at least 100 years of forest cover. Time to extinction in simulations was dependent on the duration of the periods with favourable and unfavourable conditions after management cessation, and the population sizes and growth rates in these periods. Our results thus suggest that the ability of a species to survive is a complex function of disturbance regimes, rates of successional change, and the demographic response to environmental changes. Detailed demographic studies over entire successional cycles are therefore essential to identify the environmental conditions that enable long-term persistence and to design management for species experiencing extinction debts.

Published

2016

49. Widespread latitudinal asymmetry in marginal population performance

Author

Arndt Hampe, Adhara Pardo, Johannes Kollmann, Jens-Christian Svenning, Fernando Pulido, Eva Moracho, Bastien Castagneyrol, Alistair S. Jump, Fernando Valladares, Yonatan Cáceres, Johan Ehrlén, and Francisco Rodríguez-Sánchez

Subjects

0106 biological sciences, education.field_of_study, Range (biology), Ecology, 010604 marine biology & hydrobiology, Biome, Population, Global warming, Climate change, 15. Life on land, Biology, 010603 evolutionary biology, 01 natural sciences, Taxon, Habitat, 13. Climate action, Margin (machine learning), education

Abstract

AimRange shifts are expected to occur when populations at one range margin perform better than those at the other margin, yet no global trend in population performances at range margins has been demonstrated empirically across a wide range of taxa and biomes. Here we test the prediction that, if impacts of ongoing climate change on population performance are widespread, then populations from the high-latitude margin (HLM) should perform as well as or better than central populations, whereas populations at low-latitude margins (LLM) populations should perform worse.LocationGlobalTime period1898–2020Major taxa studiedPlants and animalsMethodsTo test our prediction, we used a meta-analysis quantifying the empirical support for asymmetry in the performance of high- and low-latitude margin populations compared to central populations. Performance estimates were derived from 51 papers involving 113 margin-centre comparisons from 54 species and 705 populations. We then related these performance differences to climatic differences among populations. We also tested whether patterns are consistent across taxonomic kingdoms (plants vs. animals) and across habitats (marine vs. terrestrial).ResultsPopulations at margins performed significantly worse than central populations and this trend was primarily driven by the low-latitude margin. Although the difference was of small magnitude, it was largely consistent across biological kingdoms and habitats. The differences in performance were positively related to the difference in average temperatures between populations during the period 1985–2016.Major conclusionsThe observed asymmetry in marginal population performance confirms predictions about the effects of global climate change. It indicates that changes in demographic rates in marginal populations, despite extensive short-term variation, can serve as early-warning signals of impending range shifts.

Published

2019

50. A natural heating experiment : Phenotypic and genotypic responses of plant phenology to geothermal soil warming

Author

Bryndís Marteinsdóttir, Johan Ehrlén, and Alicia Valdés

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, media_common.quotation_subject, Climate Change, climatic variation, Iceland, Growing season, plant phenology, Caryophyllaceae, Flowers, Biology, 010603 evolutionary biology, 01 natural sciences, phenotypic plasticity, Soil, Environmental Chemistry, phenotypic selection, Geothermal gradient, 0105 earth and related environmental sciences, General Environmental Science, Local adaptation, media_common, Ekologi, Global and Planetary Change, Phenotypic plasticity, Ecology, Phenology, Reproduction, Global warming, fungi, Temperature, food and beverages, biology.organism_classification, Adaptation, Physiological, geothermal ecosystems, Cerastium fontanum, Gene-Environment Interaction, local adaptation, microclimate

Abstract

Under global warming, the survival of many populations of sedentary organisms in seasonal environments will largely depend on their ability to cope with warming in situ by means of phenotypic plasticity or adaptive evolution. This is particularly true in high-latitude environments, where current growing seasons are short, and expected temperature increases large. In such short-growing season environments, the timing of growth and reproduction is critical to survival. Here, we use the unique setting provided by a natural geothermal soil warming gradient (Hengill geothermal area, Iceland) to study the response of Cerastium fontanum flowering phenology to temperature. We hypothesized that trait expression and phenotypic selection on flowering phenology are related to soil temperature, and tested the hypothesis that temperature-driven differences in selection on phenology have resulted in genetic differentiation using a common garden experiment. In the field, phenology was related to soil temperature, with plants in warmer microsites flowering earlier than plants at colder microsites. In the common garden, plants responded to spring warming in a counter-gradient fashion; plants originating from warmer microsites flowered relatively later than those originating from colder microsites. A likely explanation for this pattern is that plants from colder microsites have been selected to compensate for the shorter growing season by starting development at lower temperatures. However, in our study we did not find evidence of variation in phenotypic selection on phenology in relation to temperature, but selection consistently favoured early flowering. Our results show that soil temperature influences trait expression and suggest the existence of genetically based variation in flowering phenology leading to counter-gradient local adaptation along a gradient of soil temperatures. An important implication of our results is that observed phenotypic responses of phenology to global warming might often be a combination of short-term plastic responses and long-term evolutionary responses, acting in different directions.

Published

2019