Spatial patterns of weed dispersal by wintering gulls within and beyond an agricultural landscape

Martín‐Vélez, Víctor; Leeuwen, Casper H. A. van; Sánchez, Marta I.; Hortas, Francisco; Shamoun‐Baranes, Judy; Thaxter, Chris B.; Lens, Luc; Camphuysen, C.J.; Green, Andy J.

doi:10.1111/1365-2745.13619

Cited by 29 publications

(46 citation statements)

References 79 publications

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“…Silva G. G. et al, 2021) showing that differences in the species composition of seeds dispersed by waterfowl species are related to their foraging behavior (note, these studies did not consider plant traits). In contrast, a study of other waterbirds in rice fields found no difference between a gull and stork species in the plants they dispersed (Martín-Vélez et al, 2021). Ours is the first study showing that both bird and plant traits drive waterfowl-seed interactions.…”

Section: Different Waterfowl Have Different Roles As Seed Vectorscontrasting

confidence: 58%

“…These birds mainly disperse seeds via gut passage (endozoochory), yet their importance for plants lacking a fleshy-fruit has been underestimated because it is ignored by widely used "dispersal syndromes" (Green et al, 2021). Many of the migratory bird species are waterbirds, which are important for the dispersal of a broad range of both aquatic and terrestrial plants between habitat patches, often facilitating dispersal at extreme distances of >100 km (Green et al, 2016(Green et al, , 2021Viana et al, 2016;Martín-Vélez et al, 2021). The waterbird group best known for seed dispersal is that of the waterfowl (Anatidae: ducks, swans and geese) (Green et al, 2016(Green et al, , 2021Soons et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Functional Traits Drive Dispersal Interactions Between European Waterfowl and Seeds

et al. 2022

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Endozoochory by waterfowl is important for a broad range of angiosperms, most of which lack a fleshy fruit. This dispersal function contributes to the formation and maintenance of plant communities and may allow range shifts for plant species under global change. However, our current understanding of what seed or plant traits are important for this dispersal mechanism, and how they relate to variation in waterbird traits, is extremely limited. We addressed this question using a unique dataset identifying the plant species whose seeds are ingested by 31 different waterfowl species in Europe. We used RLQ and fourth-corner analyses to explore relationships between (1) bird morphological and foraging strategy traits, and (2) plant traits related to seed morphology, environmental preferences, and growth form. We then used Generalized Additive Models to identify relationships between plant/seed traits and the number of waterfowl species that disperse them. Although many waterfowl feed intentionally on seeds, available seed trait data provided little explanation for patterns compared to plant traits such as Ellenberg indicators of habitat preference and life form. Geese were associated with terrestrial plants, ingesting seeds as they graze on land. Diving ducks were associated with strictly aquatic plants, ingesting seeds as they feed at greater depths. Dabbling ducks ingest seeds from plants with high light and temperature requirements, especially shoreline and ruderal species growing in or around the dynamic and shallow microhabitats favored by these birds. Overall, the number of waterfowl vector species (up to 13 per plant species) increases for plants with greater soil moisture requirements and salinity tolerance, reflecting the inclination of most waterfowl species to feed in coastal wetlands. Our findings underline the importance of waterfowl dispersal for plants that are not strictly aquatic, as well as for plants associated with high salinities. Furthermore, our results reveal a soil moisture gradient that drives seed-bird interactions, in line with differences between waterfowl groups in their microhabitat preferences along the land-water continuum. This study provides an important advance in our understanding of the interactions that define plant dispersal in wetlands and their surroundings, and of what plants might be affected by ongoing changes in the distributions of waterfowl species.

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Section: Different Waterfowl Have Different Roles As Seed Vectorscontrasting

confidence: 58%

Section: Introductionmentioning

confidence: 99%

Functional Traits Drive Dispersal Interactions Between European Waterfowl and Seeds

et al. 2022

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“…Amongst 576 species considered not to be dispersed by birds, they include 174 from genera identified as duck‐dispersed by Soons et al 2016 (including 58 taxa in common at the species level). For example, Tamme et al (2014) suggested that Juncus bufonius had an MDD (via wind) of only 100 m, yet this species is dispersed by numerous ungulates and waterbirds, including gulls providing an estimated MDD of > 200 km (Albert et al 2015a, Lovas‐Kiss et al 2019, Martín‐Vélez et al 2021b). As further examples of how databases can mislead, none of 247 Poaceae and 165 Cyperaceae species in an Australian database were considered as dispersed via endozoochory (Thomson et al 2010), yet avian endozoochory is particularly frequent in these families (Calviño‐Cancela et al 2006, Green et al 2008).…”

Section: When They Ignore Key Vectors Plant Trait Databases Are Unreliablementioning

confidence: 99%

Plant dispersal syndromes are unreliable, especially for predicting zoochory and long‐distance dispersal

Green

Baltzinger

Lovas‐Kiss

2021

Oikos

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Plant dispersal syndromes are allocated based on diaspore morphology and used to predict the dominant mechanisms of dispersal. Many authors assume that only angiosperms with endozoochory, epizoochory or anemochory syndromes have a longdistance dispersal (LDD) mechanism. Too much faith is often placed in classical syndromes to explain historical dispersal events and to predict future ones. What is usually recorded as the 'endozoochory syndrome' is in reality a 'frugivory syndrome' and this has often diverted attention from endozoochory by non-frugivores (e.g. waterbirds and large herbivores) that disperse a broad range of angiosperms, for which they likely provide the maximum dispersal distances. Neither the endozoochory nor the epizoochory syndromes provide helpful predictions of which plants non-frugivores disperse, or by which mechanism. We combined data from previous studies to show that only 4% of European plant species dispersed by ungulate endozoochory belong to the corresponding syndrome, compared to 36% for ungulate epizoochory and 8% for endozoochory by migratory ducks. In contrast, the proportions of these species that are assigned to an 'unassisted syndrome' are 37, 31 and 28%, respectively. Since allocated syndromes do not adequately account for zoochory, empirical studies often fail to find the expected relationship between syndromes and LDD events such as those underlying the colonization of islands or latitudinal migration rates. We need full incorporation of existing zoochory data into dispersal databases, and more empirical research into the relationship between plant traits and the frequency and effectiveness of different dispersal mechanisms (paying attention to unexpected vectors). Acknowledging the broad role of non-frugivores in facilitating LDD is crucial to improve predictions of the consequences of global change, such as how plant distributions respond to climate change, and how alien plants spread. Networks of dispersal interactions between these vertebrates and plants are a vital but understudied part of the Web of Life.

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“…Pellets contain undigested food items, and are normally produced at roosting sites at the end of the day. Shorter maximum gut retention times and dispersal distances are expected for propagules egested in pellets than for faeces (Martín-Vélez et al 2021b). Like seeds, small invertebrate propagules stuck on the outside of crayfish are liable to be ingested and dispersed by these birds (Lovas-Kiss et al 2018).…”

Section: Aquatic Sciencesmentioning

confidence: 99%

“…This study was carried out across seven sites in Andalusia used for roosting and feeding by L. fuscus, including ricefields (where C. ciconia were also sampled), landfills, salt pans, and a natural lake (Table 1; Fig. 1), with a known and varying extent of connectivity through direct L. fuscus flights (Martín-Vélez et al 2020, 2021b. These sites are described as follows (see Martín-Vélez et al (2020, 2021c for more details):…”

Section: Study Sitesmentioning

confidence: 99%

Dispersal of aquatic invertebrates by lesser black-backed gulls and white storks within and between inland habitats

et al. 2021

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Waterbirds can transport aquatic invertebrates internally, contributing to metapopulation dynamics between aquatic habitats in a terrestrial matrix. However, research into this dispersal process to date has focused on individual field sites or laboratory studies. We investigated the invertebrates dispersed by endozoochory by the lesser black-backed gull Larus fuscus wintering in Andalusia, south-west Spain in 2016–2017, comparing seven sites interconnected by their movements, with different degrees of anthropogenization [three landfills, two saltpan complexes, a natural lake, and a large (370 km2) ricefield area]. In the ricefields, we also compared invertebrates dispersed by gulls with those dispersed by the larger white stork Ciconia ciconia. A total of 642 intact invertebrates and their propagules (mainly plumatellid bryozoans, cladocerans, and other branchiopods) were recorded in excreta (faeces and pellets) from gulls and storks. A greater diversity and abundance of invertebrates were recorded in ricefields, notably 43 individuals of the alien snail Physella acuta. One snail was still alive in a gull pellet 3 weeks after being stored in a fridge. This represents the first record of snail dispersal within waterbird pellets. Viability was also confirmed for the cladoceran Macrothrix rosea recorded in ricefields, and the alien brine shrimp Artemia franciscana recorded mainly in saltpans. In ricefields, gulls and pellets had significantly fewer propagules and fewer taxa per gram of excreta than storks and faeces, respectively. Through their high mobility, gulls and storks can disperse invertebrates between different natural and artificial habitats, and even to landfills. They can promote metapopulation dynamics for native bryozoans and branchiopods, but also the spread of invasive snails and brine shrimp.

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Spatial patterns of weed dispersal by wintering gulls within and beyond an agricultural landscape

Cited by 29 publications

References 79 publications

Functional Traits Drive Dispersal Interactions Between European Waterfowl and Seeds

Functional Traits Drive Dispersal Interactions Between European Waterfowl and Seeds

Plant dispersal syndromes are unreliable, especially for predicting zoochory and long‐distance dispersal

Dispersal of aquatic invertebrates by lesser black-backed gulls and white storks within and between inland habitats

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