Isabel Donoso scite author profile

Seed dispersal is key to the persistence and spread of plant populations. Because the majority of plant species rely on animals to disperse their seeds, global change drivers that directly affect animals can cause cascading impacts on plant communities. In this review, we synthesize studies assessing how disperser loss alters plant populations, community patterns, multitrophic interactions, and ecosystem functioning. We argue that the magnitude of risk to plants from disperser loss is shaped by the combination of a plant species’ inherent dependence on seed dispersers and the severity of the hazards faced by their dispersers. Because the factors determining a plant species’ risk of decline due to disperser loss can be related to traits of the plants and dispersers, our framework enables a trait-based understanding of change in plant community composition and ecosystem functioning. We discuss how interactions among plants, among dispersers, and across other trophic levels also mediate plant community responses, and we identify areas for future research to understand and mitigate the consequences of disperser loss on plants globally. Expected final online publication date for the Annual Review of Ecology, Evolution, and Systematics, Volume 52 is November 2021. Please see http://www.annualreviews.org/page/journal/pubdates for revised estimates.

show abstract

Defaunation effects on plant recruitment depend on size matching and size trade-offs in seed-dispersal networks

Donoso

Schleuning

García

et al. 2017

Proc. R. Soc. B.

View full text Add to dashboard Cite

Defaunation by humans causes a loss of large animals in many ecosystems globally. Recent work has emphasized the consequences of downsizing in animal communities for ecosystem functioning. However, no study so far has integrated network theory and life-history trade-offs to mechanistically evaluate the functional consequences of defaunation in plant-animal networks. Here, we simulated an avian seed-dispersal network and its derived ecosystem function seedling recruitment to assess the relative importance of different size-related mechanisms. Specifically, we considered size matching (between bird size and seed size) and size trade-offs, which are driven by differences in plant or animal species abundance (negative size-quantity relationship) as well as in recruitment probability and disperser quality (positive size-quality relationship). Defaunation led to impoverished seedling communities in terms of diversity and seed size, but only if models accounted for size matching. In addition, size trade-off in plants, in concert with size matching, provoked rapid decays in seedling abundance in response to defaunation. These results underscore a disproportional importance of large animals for ecosystem functions. Downsizing in ecological networks will have severe consequences for ecosystem functioning, especially in interaction networks that are structured by size matching between plants and animals.

show abstract

Downsizing of animal communities triggers stronger functional than structural decay in seed-dispersal networks

et al. 2020

View full text Add to dashboard Cite

Downsizing of animal communities due to defaunation is prevalent in many ecosystems. Yet, we know little about its consequences for ecosystem functions such as seed dispersal. Here, we use eight seed-dispersal networks sampled across the Andes and simulate how downsizing of avian frugivores impacts structural network robustness and seed dispersal. We use a trait-based modeling framework to quantify the consequences of downsizing—relative to random extinctions—for the number of interactions and secondary plant extinctions (as measures of structural robustness) and for long-distance seed dispersal (as a measure of ecosystem function). We find that downsizing leads to stronger functional than structural losses. For instance, 10% size-structured loss of bird species results in almost 40% decline of long-distance seed dispersal, but in less than 10% of structural loss. Our simulations reveal that measures of the structural robustness of ecological networks underestimate the consequences of animal extinction and downsizing for ecosystem functioning.

show abstract

Phenological asynchrony in plant–butterfly interactions associated with climate: a community‐wide perspective

Donoso

Stefanescu

Martínez‐Abraín

et al. 2016

Oikos

View full text Add to dashboard Cite

Although much information has been accumulated on the effects of climate change on particular species worldwide, research aimed at assessing how such change influences biotic interactions from a community‐wide perspective is still in its infancy. We contribute to filling in this gap by analyzing a 17‐year (1996–2012) dataset that includes records of flower‐visitation interactions between 12 butterfly species and 17 plant species in a coastal wetland area in northeastern Iberian Peninsula. We assessed the extent to which temporal asynchronies between plants and adult butterflies are influenced by different climatic variables that affect both plant and insect phenologies. Temperature and degree of aridity at various monthly summaries were used as predictors of the plant–butterfly phenological asynchrony. We identified the seasonal window with the greatest effect on asynchronies for two butterfly generations (spring and summer), and assessed whether the magnitude of asynchrony is associated with the level of butterfly specialization. We used generalized linear mixed models considering a total of 39 plant–butterfly interactions. Average asynchrony was higher in the spring generation and dry conditions during winter lead to decreased temporal overlap with flowers in this butterfly generation, whereas dry conditions in the spring lead to decreased temporal overlap in the summer butterfly generation. The magnitude of the effect was consistently small at the community level (all interactions pooled). Moreover, no clear climatic trend over the study time frame was detected. Finally, specialized and generalized butterflies in their resource use as adults were similarly vulnerable to asynchronies, in contrast to previous predictions of greater mutualistic disruptions in species with narrower niches. We conclude that a least in the Mediterranean region, phenological asynchronies might be more affected by aridity level than by temperature itself, and thus the former can be a key climatic trait to make better predictions in this region.

show abstract

Community-wide seed dispersal distances peak at low levels of specialisation in size-structured networks

Sorensen

Schleuning

Donoso

et al. 2020

Preprint

View full text Add to dashboard Cite

19Network approaches provide insight into the complex web of interspecific interactions that 20 structure ecological communities. However, because data on the functional outcomes of 21 ecological networks are very rarely available, the effect of network structure on ecosystem 22 functions, such as seed dispersal, is largely unknown. Here, we develop a new approach that is 23 able to link interaction networks to a trait-based seed-dispersal model to estimate community-24 wide seed dispersal distances. We simulated networks, using a niche model based on size-25 matching between plants and birds, that varied in the degree of niche partitioning. We found that 26 community-wide dispersal distances were longest when networks had low degrees of niche 27 partitioning. We further found that dispersal distances of plant species with small fruits peaked in 28 models without niche partitioning, whereas dispersal distances of medium and large-fruited 29 plants peaked at low degrees of niche partitioning. Our simulations demonstrate that the degree 30 of niche partitioning between species is an important determinant of the ecological functions 31 derived from ecological networks and that simulation approaches can provide new insights into 32 the relationship between the structural and functional components of ecological networks. 33 34

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Isabel Donoso

Cascading Impacts of Seed Disperser Loss on Plant Communities and Ecosystems

Defaunation effects on plant recruitment depend on size matching and size trade-offs in seed-dispersal networks

Downsizing of animal communities triggers stronger functional than structural decay in seed-dispersal networks

Phenological asynchrony in plant–butterfly interactions associated with climate: a community‐wide perspective

Community-wide seed dispersal distances peak at low levels of specialisation in size-structured networks

Contact Info

Product

Resources

About