Secondary dispersal mechanisms of winged seeds: a review

Seed dispersal of Guarea glabra and G. kunthiana (Meliaceae) in Monteverde, Costa Rica was studied to determine how seed predation and secondary dispersal affect the distribution of seeds available for recruitment. The arillate seeds are consumed mainly by birds that regurgitate or defecate the seeds intact. After dispersal, 45.6% of G. glabra and 26.6% of G. kunthiana seeds were buried 1–3 cm in the soil, presumably by scatterhoarding rodents such as agoutis (Dasyprocta punctata). G. glabra seeds that were not cached were eaten mostly by beetles, and 33.7% of the seeds remained cached after 12 wk. The cached G. glabra seeds did not germinate, however, perhaps as a result of experimental procedures used to mark the seeds. In greenhouse experiments, G. glabra seeds buried to mimic scatterhoarding had higher germination success than seeds on the soil surface. G. kunthiana seeds not cached were eaten by peccaries (Tayassu tajacu) and other seed predators (60%) or were inviable (10%). Only nine (7.5%) viable G. kunthiana seeds remained in caches after 12 wk. Secondary dispersal resulted in a rearrangement of the seed shadow. G. glabra seeds were moved to sites with less leaf litter and lower vegetation density, while G. kunthiana seeds were moved farther from conspecific trees and closer to fallen logs during secondary dispersal. Considering the high rates of seed predation in the field for both species, the germination advantages for G. glabra in the greenhouse, and the shifts in microhabitat during scatterhoarding, it is likely that secondary dispersal by scatterhoarding rodents is an important stage in Guarea recruitment.RESUMEN. Dispersión de semillas de Guarea glabra y G. kunthiana (Meliaceae) en Monteverde, Costa Rica fureon examinadas para determinar como la predación de semillas y dispersión secundaria afectan la distribución de semillas disponibles para recrutamiento. Las semillas ariladas son consumidas principalmente por aves que regurgitan o defecan la semilla intacta. Luego de dispersión, 30–45% de las semillas fueron enterradas 1–3 cm en el suelo, posiblemente por roedores que disperan y acumulan como al agouti (Dasyprocta puncaata). Semillas de G. kunthiana que no fueron escondidas fueron comidas por pécaris (Tayassu tajacu) y otros predadores de semillas (60%) o no fueron viables (10%). Solo neuve (7.5%) semillas viables de G. kunthiana permanecieron en los escondites luego de 12 semanas. En contraste, semillas de G. glabra que no fueron escondidas fueron comidas mayormente por escarabajos que por pécaris, y 33.7% de las semillas permanecieron escondidas luego de 12 semanas. Las semillas esconditas de G. glabra enterradas para imitar dispersión y acumulión tuvieron una germinación mayor que semillas en la superficie del suelo. Dispersión secundaria resulto en un rearreglo de la sombra de semillas. Las dos especies experimentaron un leve aumento neto en la distancia promedio de conspecificos en frutos luego de dispersión y acumulación. Semillas de G. kunthiana fueron movidas cerca de troncos caidos durante dispersión secundaria, mientras semillas de G. glabra fueron movidas a lugares con menos lecho de hojas y baja densidad de vegetación. Considerando la alta proporción de predación de semillas en el campo para ambas especies, la ventaja de germinación de G. glabra en el invernáculo, y el cambio en micrambiente durante dispersión y acumulación, es posible que dispersión secundaria por roedores que dispersan y acumulan es importante in etapas de recrutamiento en Guarea.

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Secondary Dispersal Of Willow Seeds: Sailing On Water Into Safe Sites

Madroño ◽

10.3120/0024-9637-61.4.388 ◽

2014 ◽

Vol 61 (4) ◽

pp. 388-398 ◽

Cited By ~ 5

Author(s):

John M. Boland

Keyword(s):

Safe Sites ◽

Secondary Dispersal

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Wing loading, not terminal velocity, is the best parameter to predict capacity of diaspores for secondary wind dispersal

Journal of Experimental Botany ◽

10.1093/jxb/eraa170 ◽

2020 ◽

Vol 71 (14) ◽

pp. 4298-4307 ◽

Cited By ~ 1

Author(s):

Wei Liang ◽

Zhimin Liu ◽

Minghu Liu ◽

Xuanping Qin ◽

Carol C Baskin ◽

...

Keyword(s):

Shape Index ◽

Terminal Velocity ◽

Wind Dispersal ◽

Wing Loading ◽

Dispersal Capacity ◽

Secondary Dispersal ◽

Lift Off ◽

Best Parameter ◽

The Relationship ◽

Primary Dispersal

Abstract Lift-off velocity may be the most useful surrogate to measure the secondary dispersal capacity of diaspores. However, the most important diaspore attribute determining diaspore lift-off velocity is unclear. Furthermore, it is not known whether terminal velocity used to characterize the primary dispersal capacity of diaspores can also be used to predict their secondary wind dispersal capacity. Here, we investigate how diaspore attributes are related to lift-off velocity. Thirty-six species with diaspores differing in mass, shape index, projected area, wing loading, and terminal velocity were used in a wind tunnel to determine the relationship between diaspore attributes and lift-off velocity. We found that diaspore attributes largely explained the variation in lift-off velocity, and wing loading, not terminal velocity, was the best parameter for predicting lift-off velocity of diaspores during secondary wind dispersal. The relative importance of diaspore attributes in determining lift-off velocity was modified by both upwind and downwind slope directions and type of diaspore appendage. These findings allow us to predict diaspore dispersal behaviors using readily available diaspore functional attributes, and they indicate that wing loading is the best proxy for estimating the capacity for secondary dispersal by wind.

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Environmentally-controlled, density-dependent secondary dispersal in a local estuarine crab population

Oecologia ◽

10.1007/s00442-004-1581-8 ◽

2004 ◽

Vol 140 (2) ◽

pp. 280-288 ◽

Cited By ~ 20

Author(s):

Nathalie B. Reyns ◽

David B. Eggleston

Keyword(s):

Density Dependent ◽

Secondary Dispersal ◽

Crab Population

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Secondary dispersal by ants promotes forest regeneration after deforestation

Journal of Ecology ◽

10.1111/1365-2745.12226 ◽

2014 ◽

Vol 102 (3) ◽

pp. 659-666 ◽

Cited By ~ 29

Author(s):

Silvia C. Gallegos ◽

Isabell Hensen ◽

Matthias Schleuning

Keyword(s):

Forest Regeneration ◽

Secondary Dispersal

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Seedling recruitment, seed persistence and aspects of dispersal ecology of the invasive moth vine, Araujia sericifera (Asclepiadaceae)

Australian Journal of Botany ◽

10.1071/bt04118 ◽

2005 ◽

Vol 53 (3) ◽

pp. 225 ◽

Cited By ~ 3

Author(s):

Gabrielle Vivian-Smith ◽

F. Dane Panetta

Keyword(s):

Seedling Recruitment ◽

Seedling Emergence ◽

Field Conditions ◽

Long Distance ◽

Seed Persistence ◽

Secondary Dispersal ◽

South Eastern ◽

High Viability ◽

The Mean ◽

Dispersal Vector

We investigated germination, seedling emergence and seed persistence of the invasive moth vine (Araujia sericifera Brot.) under controlled and field conditions in south-eastern Queensland. Fresh seed showed high viability (99.5%) and germinated readily, with 97.2% of all recorded germinations occurring within 14 days. Mean germination rates ranged from 74 to 100% across the range of temperature (10/20°C, 15/25°C and 20/30°C alternating 12-h thermoperiods) and light (0- and 12-h photoperiods) treatments. Germination was significantly reduced only under cool, dark conditions. In a 24-month field experiment, seedling emergence was greatest for seeds buried at 1 cm (mean = 96.3%), intermediate for seeds buried at 5 cm (mean = 62.7%) and least for surface-sown seeds (mean = 30.7%). Seed persistence under field conditions was low, declining rapidly to 3.9% at 6 months and to 0.67% at 24 months. Moth vine’s capacity to germinate readily and the rapid depletion of seeds under field conditions indicate that the species has a transient seed bank in south-eastern Queensland. In an additional experiment testing the capacity of seeds for secondary dispersal by water, the mean floating time of seeds was 15.4 days, suggesting that water could act as a secondary dispersal vector, contributing to long-distance dispersal. We recommend that surveillance methods for detecting moth-vine populations should consider both water-flow patterns and wind direction.

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SEED REMOVAL, SEED PREDATION, AND SECONDARY DISPERSAL

Ecology ◽

10.1890/04-0847 ◽

2005 ◽

Vol 86 (3) ◽

pp. 801-806 ◽

Cited By ~ 234

Author(s):

Stephen B. Vander Wall ◽

Kellie M. Kuhn ◽

Maurie J. Beck

Keyword(s):

Seed Predation ◽

Seed Removal ◽

Secondary Dispersal

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