Directed dispersal by an abiotic vector: wetland plants disperse their seeds selectively to suitable sites along the hydrological gradient via water
Authored by Merel B Soons, Groot G Arjen de, Ramirez M Teresa Cuesta, Rob G A Fraaije, Jos T A Verhoeven, Jager Monique de
Date Published: 2017
DOI: 10.1111/1365-2435.12771
Sponsors:
European Union
Netherlands Organization for Scientific Research (NWO)
Platforms:
MATLAB
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
1. Plant species around the world invest in seed dispersal by producing
large numbers of seeds, with a wide range of morphological adaptations
that facilitate dispersal. Not all dispersed seeds reach suitable sites, however, and plants can significantly improve their fitness by
increasing the proportion of seeds arriving at suitable sites for
germination and establishment. Disproportionate dispersal to suitable
sites is known as `directed dispersal'. Yet, mechanisms of directed
dispersal are only known for a limited number of animal-dispersed plant
species.
2. We tested the hypothesis that directed dispersal can also be driven
by abiotic vectors, such as water or wind. We used a tiered approach, combining analyses of experimental, field and literature data on wetland
plant species and evaluating the potential for evolution of directed
dispersal with a spatially explicit individual-based model.
3. The data collected demonstrate that wetland plants produce seeds with
adaptations to promote transportation and deposition by water towards
microsites along the hydrological gradient where they germinate and
establish best. Aquatic species produce seeds that sink and are
transported by water as bed load towards inundated sites. In contrast, shoreline species produce seeds that float for very long periods of time
so that they are eventually entrapped by shoreline vegetation or
deposited at the waterline. Our model simulations confirm that the
patterns we observed in nature can evolve under natural selection
through adaptations in seed buoyancy.
4. For wind dispersal, the situation is more complex. Wind does not
provide directed dispersal in the strictest sense but, rather, simply
appears to be the best available dispersal vector for more terrestrial
wetland plant species to reach drier areas in a wet environment.
5. Synthesis. We show that directed dispersal towards specific, suitable
microsites is not exclusive to animal-dispersed plant species, but may
be far more common in plants - also in species dispersed by abiotic
vectors, in particular water. As water and wind are very common
dispersal vectors throughout the plant kingdom, directed dispersal (and
not just dispersal distance) seems to be of general importance for the
ecology of plants.
Tags
Biodiversity
Habitat fragmentation
Movement ecology
Long-distance dispersal
Determinants
Forest
Colonization
Communities
Life-history traits
Seed
dispersal
Vegetation patterns
Wind dispersal
Hydrochory
Riparian zones
Hydrological niche
Anemochory
Evolutionary adaptations
Plant functional traits
Water dispersal