Exposing the mechanism and timing of impact of nonindigenous species on native species
Authored by JE Byers, L Goldwasser
Date Published: 2001
DOI: 10.1890/0012-9658(2001)082[1330:etmato]2.0.co;2
Sponsors:
United States National Science Foundation (NSF)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Flow charts
Model Code URLs:
Model code not found
Abstract
The nonnative mudsnail Batillaria attramentaria was introduced to the
west coast of North America in the early part of this century and has
been displacing the native mudsnail Cerithidea californica on a
marsh-by-marsh basis. We combined detailed, quantitative field data on
this invader and its interactions with the native snail in an
individual-based model that allowed us to address both general questions
about the mechanism of displacement of native species and more specific
concerns about detecting the trajectory and impact of the invasion. In
empirically parameterized simulations the native snail was driven
extinct within 55-70 yr after introduction of Batillaria, which closely
matches direct field estimates. We then tested the relative importance
of Batillaria's demonstrated advantages in parasitism resistance
(top-down effect), exploitative competition (bottom-up effect), and
mortality rate (demographic advantage) in driving its displacement of
Cerithidea. With its demographic advantage maintained, but without its
advantages in competition and parasitism, Batillaria still drove
Cerithidea extinct within 90 yr. Only when Batillaria's mortality rate
was set equal to that of Cerithidea could the native snail persist
indefinitely, demonstrating this factor's overwhelming influence on the
success of this invasion. The difference in mortality between the
species was large relative to the other differences, but further
simulations showed that the importance of this difference stems not just
from its magnitude, but also from the sensitivity of this system to this
demographic rate. Identification of the relative importance of
mechanisms that contribute to an invader's success is one of the major
benefits of such modeling efforts.
To identify empirically measurable quantities that provide the earliest
warning of impact on the native species, we tracked many population- and
individual-level responses of Cerithidea to Batillaria's invasion, including population density, biomass, egg production, mean size, proportion of infected individuals, and individual growth rate, as well
as availability of shared food resources. We used the empirically
observed parameter values and an initial number of Batillaria invaders
in these: simulations that guaranteed extinction of Cerithidea within 90
yr. Despite a rapid initial increase in invader populations, all metrics
for Cerithidea were slow to exhibit signs of impact. Most took at least
25 yr from invasion to exhibit detectable changes, by which time the
nonnative species was established at high densities (> 3000
snails/m(2)). Cerithidea egg production was the fastest, most consistent
response metric exhibiting declines within 20-25 yr after invasion in
similar to 90\% of simulations. Difficulty in finding reliable, early
warning metrics has crucial implications for how we should view and
conduct monitoring programs and risk assessment analyses.
Tags
models
Conservation
Extinction
Invasions
Restoration
Cerithidea-californica haldeman
America
Dunes