Seed dispersal by neotropical waterfowl depends on bird species and seasonality

Silva, Giliandro G.; Green, Andy J.; Hoffman, Pedro; Weber, Vinícius; Stenert, Cristina; Lovas‐Kiss, Ádám; Maltchik, Leonardo

doi:10.1111/fwb.13615

Cited by 19 publications

(42 citation statements)

References 60 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Unlike most homosporous ferns, which disperse their spores via air currents (Barrington, 1993), spore dispersal in Isoëtes is poorly understood because they are aquatic and produce large megaspores (200-1000μm), unable to be dispersed by wind. Anecdotal evidence suggests they can be dispersed by waterways, waterfowl, or even snails and earthworms (Duthie, 1929; Jermy, 1990; Taylor & Hickey, 1992; Larsén & Rydin, 2016), and recent work has documented spores in waterfowl fecal matter (Silva et al , 2020), confirming previous observations. It is not inconceivable that sporangia, spores, or even whole plants are dispersed in the crops of these migratory animals (Les et al , 2003).…”

Section: Discussionsupporting

confidence: 75%

Revealing the evolutionary history of a reticulate polyploid complex in the genusIsoëtes

et al. 2020

Preprint

View full text Add to dashboard Cite

Polyploidy and hybridization are important processes in the evolution of spore-dispersed plants. Few studies, however, focus these dynamics in heterosporous lycophytes, such as Isoetes, where polyploid hybrids are common and thought to be important in the generation of their extant diversity. We investigate reticulate evolution in a complex of western North American quillworts (Isoetes) and provide insights into the evolutionary history of hybrids, and the role of polyploidy in maintaining novel diversity. We utilize low copy nuclear markers, whole plastomes, restriction site-associated DNA sequencing, cytology, and reproductive status (fertile or sterile) to investigate the reticulate evolutionary history of western North American Isoetes. We reconstruct the reticulate evolutionary history and directionality of hybridization events in this complex. The presence of high level polyploids, plus frequent homoploid and interploid hybridization suggests that there are low prezygotic reproductive barriers in this complex, hybridization is common and bidirectional between similar (but not divergent) cytotypes, and that allopolyploidization is important to restore fertility in some hybrid taxa. Our data provide five lines of evidence suggesting that hybridization and polyploidy can occur with frequency in the genus, and these evolutionary processes may be important in shaping extant Isoetes diversity.

show abstract

Section: Discussionsupporting

confidence: 75%

Revealing the evolutionary history of a reticulate polyploid complex in the genusIsoëtes

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…See Table 1 for full names of bird species. 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).…”

Section: Different Waterfowl Have Different Roles As Seed Vectorsmentioning

confidence: 99%

“…Interactions between plants and frugivorous birds (i.e., those feeding on fleshy-fruits) in terrestrial ecosystems are known to depend on many traits of both groups of organisms, such as fruit size and palatability and bill morphology (Wenny et al, 2016;Donoso et al, 2017). On the other hand, despite recent advances in identifying the interactions between different waterfowl and plant species in a particular community (Reynolds and Cumming, 2016;Sebastián-González et al, 2020;Silva G. G. et al, 2021), the trait associations underlying the uptake of seeds by different waterfowl species remain unknown. In general, seed ingestion by non-frugivorous vertebrates is not size limited in a manner comparable to frugivores (Chen and Moles, 2015; but see Gurd, 2008).…”

Section: Introductionmentioning

confidence: 99%

Functional Traits Drive Dispersal Interactions Between European Waterfowl and Seeds

et al. 2022

Self Cite

View full text Add to dashboard Cite

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.

show abstract

“…The behavior of birds can aid in directed and long-distance movement of bryophytes as they may act as dispersers in local sites through foraging and nesting (Calvelo et al, 2006;Parnikoza et al, 2012;Amélio et al, 2017;Parnikoza et al, 2018), and transcontinentally through migratory movements (Chmielewski & Eppley, 2019). Birds can disperse bryophytes long distances via ectozoochory, by external transportation (Lewis et al, 2014), and may be able to do this via endozoochory, through internal ingestion, as has also been shown with ferns and other herbs (Lovas-Kiss et al, 2018;Blanco et al, 2019;Hervías-Parejo et al, 2019;Silva et al, 2020).…”

Section: Introductionmentioning

confidence: 87%

Do birds disperse mosses? Evidence of endozoochory in upland geese Chloephaga picta and white-bellied seedsnipes Attagis malouinus in sub-Antarctic Chile

Lazaro¹,

Mackenzie²,

Jiménez³

2021

Preprint

View full text Add to dashboard Cite

Birds are known to act as potential vectors for the exogenous dispersal of bryophyte diaspores. Given the totipotency of vegetative tissue of many bryophytes, birds could also contribute to endozoochorous bryophyte dispersal. Research has shown that fecal samples of the upland goose (Chloephaga picta) and white-bellied seedsnipe (Attagis malouinus) contain bryophyte fragments. Although few fragments from bird feces have been known to regenerate, the evidence for the viability of diaspores following passage through the bird intestinal tract remains ambiguous. We evaluated the role of endozoochory in these same herbivorous and sympatric bird species in sub-Antarctic Chile. We hypothesized that fragments of bryophyte gametophytes retrieved from their feces are viable and capable of regenerating new plant tissue. Eleven feces disc samples containing undetermined moss fragments from C. picta (N=6) and A. malouinus (N=5) and six moss fragment samples from wild collected mosses (Conostomum tetragonum, Syntrichia robusta, and Polytrichum strictum) were grown ex situ in peat soil and in vitro using a agar-Gamborg medium. After 91 days, 20% of fragments from A. malouinus feces, 50% of fragments from C. picta feces, and 67% of propagules from wild mosses produced new growth. The fact that moss diaspores remained viable and can regenerate under experimental conditions following the passage through the intestinal tracts of these robust fliers and altitudinal and latitudinal migrants, suggests that sub-Antarctic birds may play a critical role in bryophyte dispersal. This relationship may have important implications in the way bryophytes disperse and colonize habitats facing climate change. Keywords: birds, bryophyte dispersal, endozoochory, mosses, sub-Antarctic

show abstract

Seed dispersal by neotropical waterfowl depends on bird species and seasonality

Cited by 19 publications

References 60 publications

Revealing the evolutionary history of a reticulate polyploid complex in the genusIsoëtes

Revealing the evolutionary history of a reticulate polyploid complex in the genusIsoëtes

Functional Traits Drive Dispersal Interactions Between European Waterfowl and Seeds

Do birds disperse mosses? Evidence of endozoochory in upland geese Chloephaga picta and white-bellied seedsnipes Attagis malouinus in sub-Antarctic Chile

Contact Info

Product

Resources

About