Functional Traits Drive Dispersal Interactions Between European Waterfowl and Seeds

Almeida, Bia de Arruda; Lukács, Balázs András; Lovas‐Kiss, Ádám; Reynolds, Chevonne; Green, Andy J.

doi:10.3389/fpls.2021.795288

Cited by 11 publications

(30 citation statements)

References 72 publications

(99 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Many previous studies predicting plant dispersal based on morphological dispersal syndromes overlooked such dispersal processes, and their results are thus unreliable (Green et al, 2022; Martín‐Vélez, van Leeuwen, et al, 2021). Of 35 plant species detected in mallard faecal samples in this study we found five (14%) that had not been previously detected in the diets of European Anatidae, and a further three species not previously recorded in the diet of mallards (Almeida et al, 2022, Table 2). This underlines how little we still know about endozoochory by waterfowl, and which plant species are dispersed.…”

Section: Discussionsupporting

confidence: 52%

“…β‐diversity was greatest in spring, as expected given the high number of rare, terrestrial species recorded only in that season. Similar seasonal patterns may be expected for other temperate dabbling ducks, but may differ in other waterfowl guilds, since herbivorous geese are more likely to ingest terrestrial seeds, and diving ducks are more likely to ingest seeds of submerged plants (Almeida et al, 2022). Previous studies using seeds fed to captive ducks showed that gut passage promotes earlier germination and faster establishment of P. pectinatus (Figuerola et al, 2005), and increases germinability of S. litoralis at favourable salinities (Espinar et al, 2004).…”

Section: Discussionmentioning

confidence: 67%

See 1 more Smart Citation

Plants dispersed by a non‐frugivorous migrant change throughout the annual cycle

Urgyán

Lukács

Fekete

et al. 2022

Global Ecol Biogeogr

Self Cite

View full text Add to dashboard Cite

Aim Migratory waterfowl are important endozoochory vectors for a range of plants lacking fleshy fruits. Our aim was to study the critical question of how endozoochory rates change throughout the annual cycle, and how this relates to plant life‐form and phenology. Location Lake Velence, Hungary. Time period 2017–2018. Major taxa studied Mallard (Anas platyrhynchos), Angiospermae, Charophyta. Methods We studied waterfowl endozoochory, quantifying seeds and other diaspores dispersed by mallards by collecting faecal samples monthly (ntotal = 670) at a Hungarian lake. We tested the germinability of all seeds recovered from the faecal samples. Main conclusions We extracted 5,760 seeds representing 35 plant taxa from mallard faecal samples, and 40% of these seeds germinated successfully following gut passage. We found major differences between seasons in the species composition of the seeds recovered. The peak in species diversity and in abundance of terrestrial seeds coincided with the spring migration of mallards. Importantly, endozoochory was only strongly synchronized with seed production in submerged, but not in emergent or terrestrial plants, illustrating the potential for endozoochory of seeds ingested from the soil seed bank. Overall, our results suggest that endozoochory by migratory waterfowl is a strong and underestimated driver of plant distributions, and is likely to facilitate plant range shifts under climate change, and after introduction of alien species.

show abstract

Section: Discussionsupporting

confidence: 52%

Section: Discussionmentioning

confidence: 67%

Plants dispersed by a non‐frugivorous migrant change throughout the annual cycle

Urgyán

Lukács

Fekete

et al. 2022

Global Ecol Biogeogr

Self Cite

View full text Add to dashboard Cite

show abstract

“…By contrast, waterbird endozoochory is not necessarily coupled with propagule production, because propagules can be ingested from sediments long after they were produced (Brochet et al, 2010; Urgyán et al, 2023). Thirdly, body size plays a more important role for frugivores than for waterbirds, as only species with a large gape can disperse plants with the largest fruits, whereas body size is not correlated with seed size in waterbirds and other non‐frugivores (Almeida et al, 2022; Chen & Moles, 2015). Larger waterbirds have a greater surface area available for epizoochory, but there is no evidence that this influences the probability of dispersal events (Coughlan et al, 2017; Raulings et al, 2011).…”

Section: How Do Waterbirds Differ From Other Dispersal Vectors?mentioning

confidence: 99%

“…The focus of Figuerola and Green (2002) was on aquatic ecosystems, but it has since become clear that waterbirds also disperse many terrestrial plants (Almeida et al, 2022; Kleyheeg et al, 2016; Lovas‐Kiss et al, 2019; Soons et al, 2016). Waterbirds play a major role in moving propagules within and between terrestrial and aquatic habitats.…”

Section: Introductionmentioning

confidence: 99%

Dispersal of aquatic and terrestrial organisms by waterbirds: A review of current knowledge and future priorities

et al. 2023

Self Cite

View full text Add to dashboard Cite

We review progress in our understanding of the importance of waterbirds as dispersal vectors of other organisms, and identify priorities for further research. Waterbirds are excellent for long‐distance dispersal (LDD), whereas other vectors such as fish and mammals disperse similar propagules, but over shorter distances. Empirical studies of internal and external transport by waterbirds have shown that the former mechanism generally is more important. Internal transport is widely recognised for aquatic plants and aquatic invertebrates with resting eggs, but also is important for other organisms (e.g., terrestrial flowering plants not dispersed by frugivores, bryophytes, tardigrades, fish eggs). Waterbird vectors also are important in terrestrial habitats, and provide connectivity across terrestrial–aquatic boundaries. There are important differences in the roles of different waterbird species, especially those using different habitats along the aquatic–terrestrial gradient. Early attempts to predict zoochory based on propagule morphology have been found wanting, and more research is needed into how the traits of vectors and vectored organisms (including life history, dormancy and growth traits) explain dispersal interactions. Experimental studies have focused on the potential of propagules to survive internal or external transport, and research into factors determining the establishment success of propagules after dispersal is lacking. Recent spatially explicit models of seed dispersal by waterbirds should be expanded to include invertebrate dispersal, and to compare multiple bird species in the same landscape. Network approaches have been applied to plant–waterbird dispersal interactions, and these are needed for invertebrates. Genetic studies support effective LDD of plants and invertebrates along waterbird flyways, but there remains a lack of examples at a local scale. Next Generation Sequencing and genomics should be applied to waterbird‐mediated dispersal across the landscape. More studies of biogeography, community ecology, or population genetics should integrate waterbird movements at the design stage. Zoochory research has paid little attention to the dispersal of non‐pathogenic microbes (both eukaryotic and prokaryotic). Nevertheless, there is evidence that dispersal via avian guts can be central to the connectivity of aquatic microbial metacommunities. More work on microbial dispersal by waterbirds should explore its implications for biogeochemistry, and the interchange with gut flora of other aquatic organisms. In the Anthropocene, the role of migratory waterbirds in LDD of plants and other organisms is particularly important, for example in compensating for loss of large migratory mammals and fish, allowing native species to adjust their distributions under global warming, and spreading alien species along flyways after their initial introductions by human vectors. Recent technological advances have opened exciting opportunities that should be fully exploited to further our understanding of dispersal by waterbirds.

show abstract

“…Waterbirds can occur in high densities as a result of large population sizes and seasonal aggregations (Wetlands International 2022). Although waterbirds disperse a wide range of plants in aquatic, riparian and terrestrial habitats (Soons et al 2016, Green et al 2021, Almeida et al 2022), they interact most strongly with plants more typical of aquatic habitats (Kleyheeg et al 2017) by foraging on their leaves and seeds. This suggests a strong potential for (co)evolution between waterbirds and seed traits of plants in more aquatic habitat types, as indicated by higher Ellenberg F indicator values for preferred soil moisture (Ellenberg et al 1992).…”

Section: Introductionmentioning

confidence: 99%

Seed dispersal by waterbirds: a mechanistic understanding by simulating avian digestion

et al. 2022

Self Cite

View full text Add to dashboard Cite

Waterbirds disperse plant species via ingestion and egestion of seeds (endozoochory). However, our understanding about the regulating effects of seed traits, underlying mechanisms and possible (co)evolutionary processes is limited by our traditional reliance on data from feeding experiments with living waterbirds. Here, we overcome these limitations by developing and applying a new bioassay that realistically simulates digestive processes for Anseriformes waterbirds. We test three hypotheses: 1) seed survival and germination are most affected by mechanical digestion in the waterbird gizzard; 2) seed size, hardness, imbibition and shape regulate seed survival; and 3) plants growing in aquatic habitats benefit most from endozoochory by waterbirds. Experiments with 28 200 seeds of 48 plant species demonstrated species‐specific seed survival that was entirely determined by digestion in the avian gizzard. Intestinal digestion did not affect seed survival but affected seed establishment (germinability and germination time) for 21% of the species. Large, hard seeds survived the simulations the best, in contrast to generally higher seed survival for smaller seeds during in vivo experiments. This mechanistically explains that small seeds escape digestive processes rather than being inherently more resistant (the ‘escape mechanism'), while large seeds are retained until fully digested or regurgitated (the ‘resistance and regurgitation mechanism'). Plants growing in wetter habitats had similar seed survival, but digestive processes stimulated their germinability and accelerated their germination more than for terrestrial plants. This indicates a relative advantage of endozoochory for plant species growing in wet habitats, possibly reflecting a co‐evolutionary response related to dormancy breaking by gut passage. Simulating seed gut passage using a bioassay allowed establishing mechanisms and identifying relevant seed traits involved in seed dispersal by waterbirds. This information enhances our understanding of how animal species shape plant species distributions, which is extremely relevant now that current anthropogenic pressures already severely impact plant dispersal capacities.

show abstract

Functional Traits Drive Dispersal Interactions Between European Waterfowl and Seeds

Cited by 11 publications

References 72 publications

Plants dispersed by a non‐frugivorous migrant change throughout the annual cycle

Plants dispersed by a non‐frugivorous migrant change throughout the annual cycle

Dispersal of aquatic and terrestrial organisms by waterbirds: A review of current knowledge and future priorities

Seed dispersal by waterbirds: a mechanistic understanding by simulating avian digestion

Contact Info

Product

Resources

About