Abstract
Adaptation to current and future climates can be constrained by trade‐offs between fitness‐related traits. Early seedling emergence often enhances plant fitness in seasonal environments, but if earlier emergence in response to seasonal cues is genetically correlated with lower potential to spread emergence among years (i.e., bet‐hedging), then this functional trade‐off could constrain adaptive evolution. Consequently, selection favoring both earlier within‐year emergence and greater spread of emergence among years—as is expected in more arid environments—may constrain adaptive responses to trait value combinations at which a performance gain in either function (i.e., evolving earlier within‐ or greater among‐year emergence) generates a performance loss in the other. All such trait value combinations that cannot be improved for both functions simultaneously are described as Pareto optimal and together constitute the Pareto front. To investigate how this potential emergence timing trade‐off might constrain adaptation to increasing aridity, we sourced seeds of two grasses, Stipa pulchra and Bromus diandrus, from multiple maternal lines within populations across an aridity gradient in California and examined their performance in a greenhouse experiment. We monitored emergence and assayed ungerminated seeds for viability to determine seed persistence, a metric of potential among‐year emergence spread. In both species, maternal lines with larger fractions of persistent seeds emerged later, indicating a trade‐off between within‐year emergence speed and potential among‐year emergence spread. In both species, populations on the Pareto front for both earlier emergence and larger seed persistence fraction occupied significantly more arid sites than populations off the Pareto front, consistent with the hypothesis that more arid sites impose the strongest selection for earlier within‐year emergence and greater among‐year emergence spread. Our results provide an example of how evaluating genetically based correlations within populations and applying Pareto optimality among populations can be used to detect evolutionary constraints and adaptation across environmental gradients.
Highlights
Plant populations provide some of the best examples of local adaptation to climatic conditions (e.g., Colautti & Barrett, 2013; Exposito-Alonso et al, 2018; Fournier-Level et al, 2011; Wadgymar et al, 2017), and anthropogenic climate change is expected to further require species to evolve in order to persist in novel conditions (Hoffmann & Sgro, 2011; Jump & Peñuelas, 2005)
We hypothesized that: (a) among genotypes, earlier emergence within years is associated with lower potential to spread emergence among years; (b) based on geographic patterns of trait variation among populations, selection for earlier within-year emergence and greater among-year emergence spread is stronger in more arid environments, but the evolution of both early within-year emergence and greater amongyear emergence spread is constrained; (c) plasticity in emergence timing traits in response to water availability can alter the fitness costs associated with the evolutionary constraint generated by the trade-off between within-year emergence speed and among-year emergence spread
We demonstrate that this trade-off can result in emergence timing trait values across an environmental gradient that appear suboptimal when traits are considered individually but are on the Pareto front when considered in combination
Summary
Plant populations provide some of the best examples of local adaptation to climatic conditions (e.g., Colautti & Barrett, 2013; Exposito-Alonso et al, 2018; Fournier-Level et al, 2011; Wadgymar et al, 2017), and anthropogenic climate change is expected to further require species to evolve in order to persist in novel conditions (Hoffmann & Sgro, 2011; Jump & Peñuelas, 2005). If lower soil moisture predicts less favorable growing conditions, shifting the pengiredicted phenotypic optimum toward higher seed persistence, this could promote seed persistence by decreasing the proportion of seeds that germinate (Bewley et al, 2013) or increasing the survival of non-germinating seeds (Long et al, 2015; Mordecai, 2012) Such plastic responses of emergence timing traits to water availability are consistent with predictive plasticity if they match clinal patterns of trait variation across an aridity gradient. We hypothesized that: (a) among genotypes, earlier emergence within years is associated with lower potential to spread emergence among years; (b) based on geographic patterns of trait variation among populations, selection for earlier within-year emergence and greater among-year emergence spread is stronger in more arid environments, but the evolution of both early within-year emergence and greater amongyear emergence spread is constrained; (c) plasticity in emergence timing traits in response to water availability can alter the fitness costs associated with the evolutionary constraint generated by the trade-off between within-year emergence speed and among-year emergence spread
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
