TY - JOUR
T1 - Linking patterns and processes in alpine plant communities
T2 - A global study
AU - Kikvidze, Zaal
AU - Pugnaire, Francisco I.
AU - Brooker, Robin W.
AU - Choler, Philippe
AU - Lortie, Christopher J.
AU - Michalet, Richard
AU - Callaway, Ragan M.
PY - 2005/6
Y1 - 2005/6
N2 - Predictable relationships among patterns, processes, and properties of plant communities are crucial for developing meaningful conceptual models in community ecology. We studied such relationships in 18 plant communities spread throughout nine Northern Hemisphere high-mountain subalpine and alpine meadow systems and found linear and curvilinear correlative links among temperature, precipitation, productivity, plant interactions, spatial pattern, and richness. We found that sites with comparatively mild climates have greater plant biomass, and at these sites strong competition corresponds with overdispersed distribution of plants, reducing intraspecific patchiness and in turn increasing local richness. Sites with cold climates have little biomass, and at these sites a high proportion of species benefit from strong facilitative effects of neighbors, leading to an aggregated distribution of plants. Sites with intermediate, or relatively moderate climates are intermediate in biomass, and at these sites interactions are weak (or competition may be counterbalanced by facilitation), corresponding with a nearly random distribution of plants. At these sites species richness is lower than average. We propose that the relationship between interspecific spatial pattern and community richness reflects niche differentiation and/or construction, which allows for the coexistence of more species than would be possible with random, unstructured spatial distributions. Discovering the mechanisms that drive the relationships described here would further link functional and structural components of plant communities and enhance the predictive capability of community ecology.
AB - Predictable relationships among patterns, processes, and properties of plant communities are crucial for developing meaningful conceptual models in community ecology. We studied such relationships in 18 plant communities spread throughout nine Northern Hemisphere high-mountain subalpine and alpine meadow systems and found linear and curvilinear correlative links among temperature, precipitation, productivity, plant interactions, spatial pattern, and richness. We found that sites with comparatively mild climates have greater plant biomass, and at these sites strong competition corresponds with overdispersed distribution of plants, reducing intraspecific patchiness and in turn increasing local richness. Sites with cold climates have little biomass, and at these sites a high proportion of species benefit from strong facilitative effects of neighbors, leading to an aggregated distribution of plants. Sites with intermediate, or relatively moderate climates are intermediate in biomass, and at these sites interactions are weak (or competition may be counterbalanced by facilitation), corresponding with a nearly random distribution of plants. At these sites species richness is lower than average. We propose that the relationship between interspecific spatial pattern and community richness reflects niche differentiation and/or construction, which allows for the coexistence of more species than would be possible with random, unstructured spatial distributions. Discovering the mechanisms that drive the relationships described here would further link functional and structural components of plant communities and enhance the predictive capability of community ecology.
KW - Alpine systems
KW - Climate change
KW - Competition
KW - Environmental stress
KW - Facilitation
KW - Plant interactions
KW - Precipitation
KW - Productivity
KW - Spatial pattern
KW - Species diversity
KW - Temperature
UR - http://www.scopus.com/inward/record.url?scp=20444383867&partnerID=8YFLogxK
U2 - 10.1890/04-1926
DO - 10.1890/04-1926
M3 - Article
AN - SCOPUS:20444383867
SN - 0012-9658
VL - 86
SP - 1395
EP - 1400
JO - Ecology
JF - Ecology
IS - 6
ER -