|Daneshgar, Pedram - IOWA STATE UNIVERSITY|
|Wilsey, Brian - IOWA STATE UNIVERSITY|
Submitted to: Ecological Society of America Abstracts
Publication Type: Abstract Only
Publication Acceptance Date: April 15, 2009
Publication Date: August 2, 2009
Citation: Daneshgar, P., Wilsey, B.J., Polley, H.W. 2009. Exotic plant traits lead to functional diversity decline in novel ecosystems. In: Proceedings of the Ecological Society of America, August 2-7, 2009, Albuquerque, New Mexico. 2009 CDROM. Technical Abstract: Exotic species have become common and even dominant in some grasslands forming novel ecosystems because the species in them have no common evolutionary history. Recent work on these novel ecosystems suggest that exotic species contribute to diversity declines. In order to identify the plant traits that contribute to this decline, we sampled plots in 2008 that were part of the maintenance of exotic vs. native diversity (MEND) experiment in the Blackland Prairie region of Texas. This experiment, a randomized block design comprised of two blocks (representing two planting times) uses 18 exotic and 18 native species paired for phylogeny, growth form, and mode of photosynthesis planted in plots that were either all exotic or all native as either monocultures or random draws of 9 species planted with realistic relative abundances. Draws were done so that exotic-native pairs were always selected together. We compared leaf traits (leaf area, specific leaf area (SLA), and C:N ratio), whole plant traits (species heights, biomass, and light capture) and community-level traits (relative yield in mixture) by functional group. These traits were tested in both ambient and climate change conditions. Native communities had significantly higher functional diversity than exotic communities. In exotic communities,C4 grass dominance appeared to cause functional diversity decline. With an initial relative yield of 56% in mixture at planting, exotic C4 grasses grew to 88% of the total yield at harvest resulting in the abundance decline of C3 grasses by 8%, forbs by 17%, and legumes by 7%. Exotic C4 grasses had greater leaf area, peak light capture, and SLA than native C4 grasses suggesting a greater ability to capture resources, which led to exotic C4 grasses producing the most biomass of all groups tested. Stability and functional diversity in native communities was maintained by C3 grasses and forbs. Native C4 grasses decreased in abundance by 8%, while C3 grasses increased by 3% and forbs by 12%. The native C3 grasses were taller and had six times greater biomass than their exotic counterparts, which led to greater peak light capture. Native forbs were also taller and had greater biomass than exotic forbs. Native C3 grasses and forbs were more productive than exotics despite having less leaf area and SLA suggesting greater resource use efficiency.