TY - JOUR
T1 - Microhabitat amelioration and reduced competition among understorey plants as drivers of facilitation across environmental gradients
T2 - Towards a unifying framework
AU - Soliveres, Santiago
AU - Eldridge, David J.
AU - Maestre, Fernando T.
AU - Bowker, Matthew A.
AU - Tighe, Matthew
AU - Escudero, Adrián
N1 - Funding Information:
We thank David Tongway and Nick Reid for their help during plot selection and fieldwork in Australia. Nick Reid also hosted SS during a research stay in his lab. Estrella Pastor, Nick Schultz, Megan Good, María D. Puche, Pablo García-Palacios, Erin Roger, Ian Telford, James Val and Madeleine Rankin assisted with fieldwork and/or plant identification. Peter Weston, Anthony Gibson, Kevin Mitchell, Andrew Mosely and Patty Byrne allowed us access to their properties and gave us valuable information on land management issues in semi-arid Australian woodlands. We also thank Claus Holzapfel and two anonymous reviewers for their helpful and constructive comments on a previous version of the manuscript. SS was supported by a PhD fellowship from the EXPERTAL project, funded by Fundación Biodiversidad and CINTRA S.A. This research was funded by the CEFEMED, INTERCAMBIO (BIOCON 06/105) and REMEDINAL2 (P2009/AMB-1783) projects, funded by the Universidad Rey Juan Carlos-Comunidad de Madrid, Fundación BBVA and Comunidad de Madrid, respectively. FTM acknowledges support from the European Research Council under the European Community's Seventh Framework Programme (FP7/2007-2013)/ERC Grant agreement no. 242658 (BIOCOM). DJE is supported by grant LP0882630 from the Australian Research Council, and AE by grant CGL2009-13190-C03-01 from Ministerio de Ciencia e Innovación.
PY - 2011/11/20
Y1 - 2011/11/20
N2 - Studies of facilitative interactions as drivers of plant richness along environmental gradients often assume the existence of an overarching stress gradient that equally affects the performance of all the species in a given community. However, co-existing species differ in their ecophysiological adaptations, and do not experience the same stress level under particular environmental conditions. Moreover, these studies assume a unimodal relationship between richness and biomass, which is not as general as previously thought. We ignored these assumptions to assess changes in plant-plant interactions and their effect on local species richness across environmental gradients in semi-arid areas of Spain and Australia. We aimed to understand the relative importance of direct (microhabitat amelioration) and indirect (changes in the competitive relationships among the understorey species: niche segregation, competitive exclusion or intransitivity) mechanisms that might underlie the effects of nurse plants on local species richness. By jointly studying these direct and indirect mechanisms using a unifying framework, we found that nurse plants (trees, shrubs and tussock grasses) increased local richness not only by expanding the niche of neighbouring species but also by increasing niche segregation among them, though the latter was not important in all cases. The outcome of the competition-facilitation continuum varied depending on the study area, likely because the different types of stress gradient considered. When driven by both rainfall and temperature, or rainfall alone, the community-wide importance of nurse plants remained constant (Spanish sites), or showed a unimodal relationship along the gradient (Australian sites). This study expands our understanding of the relative roles of plant-plant interactions and environmental conditions as drivers of local species richness in semi-arid environments. The results can also be used to refine predictions about the response of plant communities to environmental change, and to clarify the relative importance of biotic interactions as drivers of such responses.
AB - Studies of facilitative interactions as drivers of plant richness along environmental gradients often assume the existence of an overarching stress gradient that equally affects the performance of all the species in a given community. However, co-existing species differ in their ecophysiological adaptations, and do not experience the same stress level under particular environmental conditions. Moreover, these studies assume a unimodal relationship between richness and biomass, which is not as general as previously thought. We ignored these assumptions to assess changes in plant-plant interactions and their effect on local species richness across environmental gradients in semi-arid areas of Spain and Australia. We aimed to understand the relative importance of direct (microhabitat amelioration) and indirect (changes in the competitive relationships among the understorey species: niche segregation, competitive exclusion or intransitivity) mechanisms that might underlie the effects of nurse plants on local species richness. By jointly studying these direct and indirect mechanisms using a unifying framework, we found that nurse plants (trees, shrubs and tussock grasses) increased local richness not only by expanding the niche of neighbouring species but also by increasing niche segregation among them, though the latter was not important in all cases. The outcome of the competition-facilitation continuum varied depending on the study area, likely because the different types of stress gradient considered. When driven by both rainfall and temperature, or rainfall alone, the community-wide importance of nurse plants remained constant (Spanish sites), or showed a unimodal relationship along the gradient (Australian sites). This study expands our understanding of the relative roles of plant-plant interactions and environmental conditions as drivers of local species richness in semi-arid environments. The results can also be used to refine predictions about the response of plant communities to environmental change, and to clarify the relative importance of biotic interactions as drivers of such responses.
KW - Competitive exclusion model
KW - Niche expansion
KW - Niche segregation
KW - Plant-plant interactions
KW - Richness-biomass relationship
KW - Stress-gradient hypothesis
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U2 - 10.1016/j.ppees.2011.06.001
DO - 10.1016/j.ppees.2011.06.001
M3 - Article
AN - SCOPUS:82455199246
SN - 1433-8319
VL - 13
SP - 247
EP - 258
JO - Perspectives in Plant Ecology, Evolution and Systematics
JF - Perspectives in Plant Ecology, Evolution and Systematics
IS - 4
ER -