Foliar damage beyond species distributions is partly explained by distance dependent interactions with natural enemies

Plant distributions are expected to shift in response to climate change, and range expansion dynamics will be shaped by the performance of individuals at the colonizing front. These plants will encounter new biotic communities beyond their range edges, and the net outcome of these encounters could p...

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Bibliographic Details
Published in:Ecology (Durham) 2016-09, Vol.97 (9), p.2331-2341
Main Authors: Katz, Daniel S. W., Ibáñez, Inés
Format: Article
Language:English
Subjects:
Acer rubrum
Adults
Animal behavior
Biogeography
biotic interactions
Carya glabra
Climate
Climate change
Colonization
Conspecifics
distance dependence
Enemy Release Hypothesis
Flowers & plants
foliar disease
Herbivores
Herbivory
Janzen‐Connell Hypothesis
Liriodendron tulipifera
Natural enemies
Plant diseases
Plants (botany)
Quercus alba
Quercus velutina
range expansion
Range extension
recruitment
Robinia pseudoacacia
Seedlings
Spatial distribution
Species
species distributions
temperate forests
transplant experiment
Trees
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Summary:Plant distributions are expected to shift in response to climate change, and range expansion dynamics will be shaped by the performance of individuals at the colonizing front. These plants will encounter new biotic communities beyond their range edges, and the net outcome of these encounters could profoundly affect colonization success. However, little is known about how biotic interactions vary across range edges and this has hindered efforts to predict changes in species distributions in response to climate change. In contrast, a rich literature documents how biotic interactions within species ranges vary according to distance to and density of conspecific individuals. Here, we test whether this framework can be extended to explain how biotic interactions differ beyond range edges, where conspecific adults are basically absent. To do so, we planted seven species of trees along a 450-km latitudinal gradient that crossed the current distributional range of five of these species and monitored foliar disease and invertebrate herbivory over 5 yr. Foliar disease and herbivory were analyzed as a function of distance to and density of conspecific and congeneric trees at several spatial scales. We found that within species ranges foliar disease was lower for seedlings that were farther from conspecific adults for Acer rubrum, Carya glabra, Quercus alba, and Robinia pseudoacacia. Beyond range edges, there was even less foliar disease for C. glabra, Q. alba, and R. pseudoacacia (A. rubrum was not planted outside its range). Liriodendron tulipifera did not experience reduced disease within or beyond its range. In contrast, Quercus velutina displayed significant but idiosyncratic patterns in disease at varying distances from conspecifics. Patterns of distance dependent herbivory across spatial scales was generally weak and in some cases negative (i.e., seedlings farther from conspecific adults had more herbivory). Overall, we conclude that differences in biotic interactions across range edges can be thought of as a spatial extension to the concept of distance dependent biotic interactions. This framework also provides the basis for general predictions of how distance dependent biotic interactions will change across range edges in other systems.
ISSN:0012-9658
1939-9170
DOI:10.1002/ecy.1468