Joint Effects of Habitat Heterogeneity and Species' Life-History Traits on Population Dynamics in Spatially Structured Landscapes
Authored by Xinping Ye, Tiejun Wang, Andrew K Skidmore
Date Published: 2014
DOI: 10.1371/journal.pone.0107742
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Platforms:
R
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Abstract
Both habitat heterogeneity and species' life-history traits play
important roles in driving population dynamics, yet there is little
scientific consensus around the combined effect of these two factors on
populations in complex landscapes. Using a spatially explicit
agent-based model, we explored how interactions between habitat spatial
structure (defined here as the scale of spatial autocorrelation in
habitat quality) and species life-history strategies (defined here by
species environmental tolerance and movement capacity) affect population
dynamics in spatially heterogeneous landscapes. We compared the
responses of four hypothetical species with different life-history
traits to four landscape scenarios differing in the scale of spatial
autocorrelation in habitat quality. The results showed that the
population size of all hypothetical species exhibited a substantial
increase as the scale of spatial autocorrelation in habitat quality
increased, yet the pattern of population increase was shaped by species'
movement capacity. The increasing scale of spatial autocorrelation in
habitat quality promoted the resource share of individuals, but had
little effect on the mean mortality rate of individuals. Species'
movement capacity also determined the proportion of individuals in
high-quality cells as well as the proportion of individuals experiencing
competition in response to increased spatial autocorrelation in habitat
quality. Positive correlations between the resource share of individuals
and the proportion of individuals experiencing competition indicate that
large-scale spatial autocorrelation in habitat quality may mask the
density-dependent effect on populations through increasing the resource
share of individuals, especially for species with low mobility. These
findings suggest that low-mobility species may be more sensitive to
habitat spatial heterogeneity in spatially structured landscapes. In
addition, localized movement in combination with spatial autocorrelation
may increase the population size, despite increased density effects.
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