Skip to main content
Dryad logo

Data from: Foraging decisions with conservation consequences: Interaction between beavers and invasive tree species

Citation

Juhász, Erika et al. (2022), Data from: Foraging decisions with conservation consequences: Interaction between beavers and invasive tree species, Dryad, Dataset, https://doi.org/10.5061/dryad.cz8w9gj5s

Abstract

Herbivore species can either hinder or accelerate the invasion of woody species through selective utilization. Therefore, an exploration of foraging decisions can contribute to the understanding and forecasting of woody plant invasions. Despite the large distribution range and rapidly growing abundance of beaver species across the Northern Hemisphere, only a few studies focus on the interaction between the beaver and invasive woody plants.

We collected data on the woody plant supply and utilization at 20 study sites in Hungary, at two fixed distances from the water. The following parameters were registered: taxon, trunk diameter, type of utilization, and carving depth. Altogether 5401 units (trunks and thick branches) were identified individually. We developed a statistical protocol that uses a dual approach, combining whole-database and transect-level analyses to examine foraging strategy.

Taxon, diameter, and distance from water all had a significant effect on foraging decisions. The order of preference for the four most abundant taxa was: Populus spp. (softwood), Salix spp. (softwood), Fraxinus pennsylvanica (invasive hardwood), Acer negundo (invasive hardwood). The diameter influenced the type of utilization, as units with greater diameter were rather carved or debarked than felled. According to the central-place foraging strategy, intensity of the foraging decreased with the distance from the water, while both the taxon and diameter selectivity increased. This suggests stronger modification of the woody vegetation directly along the waterbank, together with a weaker impact further from the water.

In contrast to invasive trees, for which utilization occurred almost exclusively in the smallest diameter class, even the largest softwood trees were utilized by means of carving and debarking. This may lead to the gradual loss of softwoods or the transformation of them into shrubby form. After the return of the beaver, mature stages of softwood stands and thus the structural heterogeneity of floodplain woody vegetation could be supported by the maintenance of sufficiently large active floodplains.

The beaver accelerates the shift of the canopy layer’s species composition towards invasive hardwood species, supporting the enemy release hypothesis. However, the long-term impact will also depend on how plants respond to different types of utilization and on their ability to regenerate, which are still unexplored issues in this environment. Our results should be integrated with knowledge about factors influencing the competitiveness of the studied native and invasive woody species to support floodplain conservation and reconstruction.

Methods

Full data processing methodology is available in the associated manuscript and its appendices.

Funding

Blue Planet Climate Protection Foundation Research Scholarship

Hungarian National Research, Development and Innovation Office, Award: GINOP-2.3.2-15-2016-00019

Biological Doctoral School of Eötvös Loránd University’s Faculty of Science