From Latrines to Landscapes:
Effects of Spatial and Temporal Variation in
Nutrient Transport by Costal river Otters on Terrestrial
Communities
Description:
As in human societies, the natural environment is
connected through a wide range of transport, propagation and
communication processes. Fluxes of energy and matter between
ecosystems modify food web interactions and nutrient
cycling, and affect the diversity of plants, animals, and
other organisms. Spatial linkages of ecosystems may be
interrupted, however, by disruption in transport processes
through time. Thus, ecological processes at any point in
space can be affected by past and present flows of energy
and nutrients. In order to understand complex ecological
processes such as these we must explore the spatial and
temporal variation, or ecological topology, of such
phenomena. River otters (Lontra canadensis) transport
nutrients from sea to land by feeding in the marine
environment and using latrine sites along the coast. Thus,
the behavioral dynamics of coastal river otter populations
provides an excellent model system to explore the effects of
spatial and temporal variation in inputs of marine carbon
(C), nitrogen (N), and phosphorus (P) to terrestrial plants
and soil organisms. Sociality in otters is solely driven by
the benefits of cooperative foraging on schooling pelagic
fishes. Therefore, any changes in the abundance and
distribution of these prey through global warming,
pollution, or harvest, could change the transport of
nutrients to otter latrines. Using stable isotope analyses
and genetic markers we will quantify the variation of
nutrient transport by river otters and explore its effects
on the diversity of the soil microbial community, nutrient
cycling, plant uptake of marine nutrients, diversity of
plants, plant growth, flowering and fruiting success. After
establishing these responses to the variation in otter
fertilization, we will develop a spatial model that will
evaluate potential changes to the terrestrial landscape
based on the distributions of schooling fish, otter
activity, and C, N, and P transport by river otters, in
response to climate change. Dates:
FY 2006 through FY 2008 Funding Sponsor:
National Science Foundation Principal Investigator:
M. BenDavid
Co-Principal Investigator:
Nathan Nibbelink
C. Meyer
J. Gulledge
Other personnel:
None
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