Pre‐dispersal seed predation and pollen limitation constrain population growth across the geographic distribution of <i>Astragalus utahensis</i>

Baer, Kathryn C.; Maron, John L.

doi:10.1111/1365-2745.12932

Cited by 31 publications

(34 citation statements)

References 83 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The discrete seedling stage of each model comprised constants calculated from rates of seedling survival and the size of surviving seedlings for each transition. The results of a seed addition experiment (Baer & Maron, ) informed the constants that described estimated recruitment from seeds produced in the previous season and from the seed bank; these remained identical for each transition year within a population. We calculated these constants by sowing seeds sourced from within the same study population in replicate blocks located throughout each study population.…”

Section: Methodsmentioning

confidence: 90%

“…Plant size was defined as the area of the basal rosette and calculated using measures of the diameter according to the formula for the area of an ellipse. Basal rosette area is strongly correlated with other measures of plant size such as above‐ground biomass (Baer & Maron, ). We calculated yearly growth rates by comparing the size of a plant from each year to the subsequent year.…”

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

Declining demographic performance and dispersal limitation influence the geographic distribution of the perennial forb Astragalus utahensis (Fabaceae)

Maron

2018

Journal of Ecology

Self Cite

View full text Add to dashboard Cite

1.A central goal of ecology is understanding the determinants of species' distributions. "Metapopulation" models for the existence of distributional boundaries predict that species' geographic ranges arise from the landscape-scale deterioration of habitat suitability towards the range edge (i.e., niche mechanisms), which simultaneously hinders demographic performance and limits dispersal to suitable habitat beyond the edge (i.e., dispersal limitation). However, few studies have examined both of these mechanisms for the same species by examining abundance and comprehensive measures of demographic performance across the distribution and beyond its boundary.2. We tested the predictions of metapopulation models for range limits by contrasting abundance, demographic performance, and population growth (λ) of the perennial forb Astragalus utahensis in central and northern range edge populations.We tested for dispersal limitation by transplanting individuals at and beyond the northern range boundary and monitoring their demographic performance.3. Astragalus abundance and stochastic λ decreased from the range centre to the northern range edge, with stochastic λ falling to or below replacement in range edge populations. However, transplants at some sites beyond the northern range edge survived and reproduced at levels similar to transplants within the range.Thus, in addition to deteriorating conditions at the range edge, dispersal limitation appears to contribute to limiting A. utahensis' northern distribution. Synthesis.Our results support metapopulation models for range limits by suggesting that decreased demographic performance constrains the viability of range edge populations while contributing to dispersal limitation of Astragalus utahensis' distribution. Thus, the tandem action of niche and dispersal processes appears to play an important role in constraining this species' northern latitudinal range. K E Y W O R D Sabundant centre hypothesis, Astragalus utahensis, biogeography and macroecology, dispersal limitation, integral projection model, metapopulation model, niche limit, population growth, range limit, transplant

show abstract

Section: Methodsmentioning

confidence: 90%

Section: Methodsmentioning

confidence: 99%

Declining demographic performance and dispersal limitation influence the geographic distribution of the perennial forb Astragalus utahensis (Fabaceae)

Maron

2018

Journal of Ecology

Self Cite

View full text Add to dashboard Cite

show abstract

“…Given the strong effects of herbivory on individual plant fitness, population growth, and local and elevational distributions (Louda 1982;Quinn 1986;Bruelheide and Scheidel 1999;Fine et al 2004), it is surprising that only one recent study has examined herbivory's role in modulating plant species' geographic ranges (Baer and Maron 2018). To our knowledge, ours is the first study to explore the effects of herbivory on a geographic range limit using experimental transplants beyond the range boundary, which is optimal for the testing of range limit hypotheses.…”

Section: Generality Of a Generalist Predator Enforcing Range Limitsmentioning

confidence: 99%

“…Given the central role of environmental gradients in structuring species' distributions, identifying important gradients is usually a first goal of range limit studies, with climatic variables being likely candidates. While climatic niche limits often do explain species' distributions (Lee-Yaw et al 2016), it is increasingly recognized that biotic interactions can contribute to large-scale distributional limits (Bruelheide and Scheidel 1999;Hochberg and Ives 1999;Case and Taper 2000;Briers 2003;Case et al 2005;deRivera et al 2005;Araújo and Luoto 2007;Holt and Barfield 2009;Gravel et al 2011;Stanton-Geddes and Anderson 2011;Moeller et al 2012;HilleRisLambers et al 2013;Afkhami et al 2014;Hargreaves et al 2014;Louthan et al 2015;Baer and Maron 2018). However, most evidence for biotic interactions influencing range limits is correlational, and there is a paucity of empirical studies that connect spatial gradients in biotic interactions to population demography and the geographic range limits of native species (Louthan et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Biotic Interactions Contribute to the Geographic Range Limit of an Annual Plant: Herbivory and Phenology Mediate Fitness beyond a Range Margin

Benning

Eckhart

Geber

et al. 2019

The American Naturalist

View full text Add to dashboard Cite

Species' geographic distributions have already shifted during the Anthropocene. However, we often do not know what aspects of the environment drive range dynamics, much less which traits mediate organisms' responses to these environmental gradients. Most studies focus on possible climatic limits to species' distributions and have ignored the role of biotic interactions, despite theoretical support for their importance in setting distributional limits. We used field experiments and simulations to estimate contributions of mammalian herbivory to a range boundary in the Californian annual plant Clarkia xantiana ssp. xantiana. A steep gradient of increasing probability of herbivory occurred across the boundary, and a reanalysis of prior transplant experiments revealed that herbivory drove severalfold declines in lifetime fitness at and beyond the boundary. Simulations showed that populations could potentially persist beyond the range margin in the absence of herbivory. Using data from a narrowly sympatric subspecies, Clarkia xantiana parviflora, we also showed that delayed phenology is strongly associated with C. xantiana ssp. xantiana's susceptibility to herbivory and low fitness beyond its border. Overall, our results provide some of the most comprehensive evidence to date of how the interplay of demography, traits, and spatial gradients in species interactions can produce a geographic range limit, and they lend empirical support to recent developments in range limits theory.

show abstract

“…As far back as Darwin (1859), it was proposed that biotic interactions could set geographic range limits, and this idea is well supported by theory (Hochberg and Ives 1999;Case and Taper 2000;Gravel et al 2011). Empirical evidence, especially experimental tests, is relatively scarce, but studies have supported the notion that mutualists (Moeller et al 2012;Afkhami et al 2014), competitors (Bullock et al 2000;Ettinger and HilleRisLambers 2017), and predators (Bruelheide and Scheidel 1999;deRivera et al 2005;Baer and Maron 2018;Benning et al 2019) can influence the location of geographic range limits.…”

mentioning

confidence: 98%

Maladaptation beyond a geographic range limit driven by antagonistic and mutualistic biotic interactions across an abiotic gradient

Benning

Moeller

2019

Evolution

View full text Add to dashboard Cite

Species’ geographic range limits often result from maladaptation to the novel environments beyond the range margin. However, we rarely know which aspects of the n‐dimensional environment are driving this maladaptation. Especially of interest is the influence of abiotic versus biotic factors in delimiting species’ distributions. We conducted a 2‐year reciprocal transplant experiment involving manipulations of the biotic environment to explore how spatiotemporal gradients in precipitation, fatal mammalian herbivory, and pollination affected lifetime fitness within and beyond the range of the California annual plant, Clarkia xantiana ssp. xantiana. In the first, drier year of the experiment, fitness outside the range edge was limited mainly by low precipitation, and there was some evidence for local adaptation within the range. In the second, wetter year, we did not observe abiotic limitations to plant fitness outside the range; instead biotic interactions, especially herbivory, limited fitness outside the range. Together, protection from herbivory and supplementation of pollen resulted in three‐ to sevenfold increases in lifetime fitness outside the range margin in the abiotically benign year. Overall, our work demonstrates the importance of biotic interactions, particularly as they interact with the abiotic environment, in determining fitness beyond geographic range boundaries.

show abstract

Pre‐dispersal seed predation and pollen limitation constrain population growth across the geographic distribution of Astragalus utahensis

Cited by 31 publications

References 83 publications

Declining demographic performance and dispersal limitation influence the geographic distribution of the perennial forb Astragalus utahensis (Fabaceae)

Declining demographic performance and dispersal limitation influence the geographic distribution of the perennial forb Astragalus utahensis (Fabaceae)

Biotic Interactions Contribute to the Geographic Range Limit of an Annual Plant: Herbivory and Phenology Mediate Fitness beyond a Range Margin

Maladaptation beyond a geographic range limit driven by antagonistic and mutualistic biotic interactions across an abiotic gradient

Contact Info

Product

Resources

About