Architectural and growth traits differ in effects on performance of clonal plants: an analysis using a field-parameterized simulation model
Authored by Deborah E Goldberg, Radka Wildova, Laura Gough, Tomas Herben, Chad Hershock
Date Published: 2007
DOI: 10.1111/j.2007.0030-1299.15430.x
Sponsors:
Czech Science Foundation
United States National Science Foundation (NSF)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
Individual traits are often assumed to be linked in a straightforward
manner to plant performance and processes such as population growth, competition and community dynamics. However, because no trait functions
in isolation in an organism, the effect of any one trait is likely to be
at least somewhat contingent on other trait values. Thus, to the extent
that the suite of trait values differs among species, the magnitude and
even direction of correlation between values of any particular trait and
performance is likely to differ among species. Working with a group of
clonal plant species, we assessed the degree of this contingency and
therefore the extent to which the assumption of simple and general
linkages between traits and performance is valid. To do this, we
parameterized a highly calibrated, spatially explicit, individual-based
model of clonal plant population dynamics and then manipulated one trait
at a time in the context of realistic values of other traits for each
species. The model includes traits describing growth, resource
allocation, response to competition, as well as architectural traits
that determine spatial spread. The model was parameterized from a
short-term (3 month) experiment and then validated with a separate, longer term (two year) experiment for six clonal wetland sedges, Carex
lasiocarpa, Carex sterilis, Carex stricta, Cladium mariscoides, Scirpus
acutus and Scirpus americanus. These plants all co-occur in fens in
southeastern Michigan and represent a spectrum of clonal growth forms
from strong clumpers to runners with long rhizomes.
Varying growth, allocation and competition traits produced the largest
and most uniform responses in population growth among species, while
variation in architectural traits produced responses that were smaller
and more variable among species. This is likely due to the fact that
growth and competition traits directly affect mean ramet size and number
of ramets, which are direct components of population biomass. In
contrast, architectural and allocation traits determine spatial
distribution of biomass; in the long run, this also affects population
size, but its net effect is more likely to be mediated by other traits.
Such differences in how traits affect plant performance are likely to
have implications for interspecific interactions and community
structure, as well as on the interpretation and usefulness of single
trait optimality models.
Tags
Competition
Community
Light
ecology
Integration
Populations
Consequences
Grassland
Solidago-altissima
Size inequalities