Effects of Growing Conditions and Source Habitat on Plant Traits and Functional Group Definition

1. Plant functional groups are used to describe patterns of community organization. However, they are defined either by suites of correlated traits or by species groupings, and the responses of these two definitions to changing environmental conditions are unknown. 2. We assessed 14 growth and morph...

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Bibliographic Details
Published in:Functional ecology 2001-02, Vol.15 (1), p.85-95
Main Authors: Dyer, A. R., Goldberg, D. E., Turkington, R., Sayre, C.
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
annual species
Biological and medical sciences
Biological taxonomies
cluster analysis
environmental change
Forbs
Fundamental and applied biological sciences. Psychology
Habitats
Human ecology
Israel
Legumes
Phenotypic traits
Plant growth
Plant roots
Plants
Principal components analysis
resource availability
Synecology
Terrestrial ecosystems
trait correlations
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Summary:1. Plant functional groups are used to describe patterns of community organization. However, they are defined either by suites of correlated traits or by species groupings, and the responses of these two definitions to changing environmental conditions are unknown. 2. We assessed 14 growth and morphological traits under low- and high-resource conditions of 42 annual plant species from two source communities in Israel that differed in resource availability. As current theory predicts, plants growing in the high-resource treatment were larger, had twofold greater relative growth rate (RGR) and thinner leaves, and allocated less biomass to roots than plants grown in the low-resource treatment. Differences in these traits were less consistent between the two source communities. Instead, taxonomic groups (grasses, legumes and a group of other forbs), regardless of source, differed in most characteristics. 3. Three general groups of species (functional groups) were identified in both resource treatments using cluster analysis on all 14 traits. In both resource treatments monocots were almost completely separated into one distinct cluster, regardless of source habitat, while the two other, mainly dicot, clusters were partially separated by habitat. However, the species composition and trait characterization of the dicot clusters differed strongly between treatments. Under low-resource conditions the two dicot clusters were separated by size traits and seed mass, but under high-resource conditions, they were separated by above-ground size, morphology and RGR. 4. Principal components analysis demonstrated inconsistency in relationships among traits and species groupings between treatments. The first two principal components emphasized different aspects of growth depending on the treatment; the third axis was defined by growth rates. As with the cluster analysis, plots of species scores revealed relatively little separation of species by habitat. 5. The response of each species varies for different traits and with growing conditions. Variation may differ among species within a functional group, producing different definitions of functional groups under different experimental conditions. Because most functional group analyses are performed on data collected without manipulation of growing conditions, conclusions concerning the response of species or communities to changes in environmental conditions may be problematic.
ISSN:0269-8463
1365-2435
DOI:10.1046/j.1365-2435.2001.00487.x