Can community structure track sea‐level rise? Stress and competitive controls in tidal wetlands

Climate change impacts, such as accelerated sea‐level rise, will affect stress gradients, yet impacts on competition/stress tolerance trade‐offs and shifts in distributions are unclear. Ecosystems with strong stress gradients, such as estuaries, allow for space‐for‐time substitutions of stress facto...

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Veröffentlicht in:	Ecology and evolution 2017-02, Vol.7 (4), p.1276-1285
Hauptverfasser:	Schile, Lisa M., Callaway, John C., Suding, Katharine N., Kelly, N. Maggi
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Sprache:	eng
Schlagworte:	Biomass Climate change Community structure competition Ecosystem assessment Ecosystems Elevation Environmental changes Environmental impact Estuaries Estuarine environments facilitation Hypotheses Original Research Predictions Redox potential Salinity Salinity effects Schoenoplectus Schoenoplectus acutus Schoenoplectus americanus Sea level Sea level rise Species Stress Stresses tidal wetlands Wetlands
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creator	Schile, Lisa M. Callaway, John C. Suding, Katharine N. Kelly, N. Maggi
description	Climate change impacts, such as accelerated sea‐level rise, will affect stress gradients, yet impacts on competition/stress tolerance trade‐offs and shifts in distributions are unclear. Ecosystems with strong stress gradients, such as estuaries, allow for space‐for‐time substitutions of stress factors and can give insight into future climate‐related shifts in both resource and nonresource stresses. We tested the stress gradient hypothesis and examined the effect of increased inundation stress and biotic interactions on growth and survival of two congeneric wetland sedges, Schoenoplectus acutus and Schoenoplectus americanus. We simulated sea‐level rise across existing marsh elevations and those not currently found to reflect potential future sea‐level rise conditions in two tidal wetlands differing in salinity. Plants were grown individually and together at five tidal elevations, the lowest simulating an 80‐cm increase in sea level, and harvested to assess differences in biomass after one growing season. Inundation time, salinity, sulfides, and redox potential were measured concurrently. As predicted, increasing inundation reduced biomass of the species commonly found at higher marsh elevations, with little effect on the species found along channel margins. The presence of neighbors reduced total biomass of both species, particularly at the highest elevation; facilitation did not occur at any elevation. Contrary to predictions, we documented the competitive superiority of the stress tolerator under increased inundation, which was not predicted by the stress gradient hypothesis. Multifactor manipulation experiments addressing plant response to accelerated climate change are integral to creating a more realistic, valuable, and needed assessment of potential ecosystem response. Our results point to the important and unpredicted synergies between physical stressors, which are predicted to increase in intensity with climate change, and competitive forces on biomass as stresses increase. We simulated sea‐level rise to test the effect of increased inundation and biotic interactions on plant growth of two wetland species to examine whether climate change impacts could alter competition/stress tolerance trade‐offs or resulting shifts in distributions. Increasing inundation reduced biomass of the species commonly found at higher marsh elevations, with little effect on the species found along channel margins, and we documented the competitive superiority of the stress
doi_str_mv	10.1002/ece3.2758
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Stress and competitive controls in tidal wetlands</title><source>Wiley Online Library Open Access</source><source>DOAJ Directory of Open Access Journals</source><source>Wiley Online Library Journals Frontfile Complete</source><source>Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals</source><source>PubMed Central</source><creator>Schile, Lisa M. ; Callaway, John C. ; Suding, Katharine N. ; Kelly, N. Maggi</creator><creatorcontrib>Schile, Lisa M. ; Callaway, John C. ; Suding, Katharine N. ; Kelly, N. Maggi</creatorcontrib><description>Climate change impacts, such as accelerated sea‐level rise, will affect stress gradients, yet impacts on competition/stress tolerance trade‐offs and shifts in distributions are unclear. Ecosystems with strong stress gradients, such as estuaries, allow for space‐for‐time substitutions of stress factors and can give insight into future climate‐related shifts in both resource and nonresource stresses. We tested the stress gradient hypothesis and examined the effect of increased inundation stress and biotic interactions on growth and survival of two congeneric wetland sedges, Schoenoplectus acutus and Schoenoplectus americanus. We simulated sea‐level rise across existing marsh elevations and those not currently found to reflect potential future sea‐level rise conditions in two tidal wetlands differing in salinity. Plants were grown individually and together at five tidal elevations, the lowest simulating an 80‐cm increase in sea level, and harvested to assess differences in biomass after one growing season. Inundation time, salinity, sulfides, and redox potential were measured concurrently. As predicted, increasing inundation reduced biomass of the species commonly found at higher marsh elevations, with little effect on the species found along channel margins. The presence of neighbors reduced total biomass of both species, particularly at the highest elevation; facilitation did not occur at any elevation. Contrary to predictions, we documented the competitive superiority of the stress tolerator under increased inundation, which was not predicted by the stress gradient hypothesis. Multifactor manipulation experiments addressing plant response to accelerated climate change are integral to creating a more realistic, valuable, and needed assessment of potential ecosystem response. Our results point to the important and unpredicted synergies between physical stressors, which are predicted to increase in intensity with climate change, and competitive forces on biomass as stresses increase. We simulated sea‐level rise to test the effect of increased inundation and biotic interactions on plant growth of two wetland species to examine whether climate change impacts could alter competition/stress tolerance trade‐offs or resulting shifts in distributions. Increasing inundation reduced biomass of the species commonly found at higher marsh elevations, with little effect on the species found along channel margins, and we documented the competitive superiority of the stress tolerator under increased inundation, which was not predicted by the stress/competition trade‐off model. 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Maggi</creatorcontrib><title>Can community structure track sea‐level rise? Stress and competitive controls in tidal wetlands</title><title>Ecology and evolution</title><addtitle>Ecol Evol</addtitle><description>Climate change impacts, such as accelerated sea‐level rise, will affect stress gradients, yet impacts on competition/stress tolerance trade‐offs and shifts in distributions are unclear. Ecosystems with strong stress gradients, such as estuaries, allow for space‐for‐time substitutions of stress factors and can give insight into future climate‐related shifts in both resource and nonresource stresses. We tested the stress gradient hypothesis and examined the effect of increased inundation stress and biotic interactions on growth and survival of two congeneric wetland sedges, Schoenoplectus acutus and Schoenoplectus americanus. We simulated sea‐level rise across existing marsh elevations and those not currently found to reflect potential future sea‐level rise conditions in two tidal wetlands differing in salinity. Plants were grown individually and together at five tidal elevations, the lowest simulating an 80‐cm increase in sea level, and harvested to assess differences in biomass after one growing season. Inundation time, salinity, sulfides, and redox potential were measured concurrently. As predicted, increasing inundation reduced biomass of the species commonly found at higher marsh elevations, with little effect on the species found along channel margins. The presence of neighbors reduced total biomass of both species, particularly at the highest elevation; facilitation did not occur at any elevation. Contrary to predictions, we documented the competitive superiority of the stress tolerator under increased inundation, which was not predicted by the stress gradient hypothesis. 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Increasing inundation reduced biomass of the species commonly found at higher marsh elevations, with little effect on the species found along channel margins, and we documented the competitive superiority of the stress tolerator under increased inundation, which was not predicted by the stress/competition trade‐off model. 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Maggi</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Can community structure track sea‐level rise? Stress and competitive controls in tidal wetlands</atitle><jtitle>Ecology and evolution</jtitle><addtitle>Ecol Evol</addtitle><date>2017-02</date><risdate>2017</risdate><volume>7</volume><issue>4</issue><spage>1276</spage><epage>1285</epage><pages>1276-1285</pages><issn>2045-7758</issn><eissn>2045-7758</eissn><abstract>Climate change impacts, such as accelerated sea‐level rise, will affect stress gradients, yet impacts on competition/stress tolerance trade‐offs and shifts in distributions are unclear. Ecosystems with strong stress gradients, such as estuaries, allow for space‐for‐time substitutions of stress factors and can give insight into future climate‐related shifts in both resource and nonresource stresses. We tested the stress gradient hypothesis and examined the effect of increased inundation stress and biotic interactions on growth and survival of two congeneric wetland sedges, Schoenoplectus acutus and Schoenoplectus americanus. We simulated sea‐level rise across existing marsh elevations and those not currently found to reflect potential future sea‐level rise conditions in two tidal wetlands differing in salinity. Plants were grown individually and together at five tidal elevations, the lowest simulating an 80‐cm increase in sea level, and harvested to assess differences in biomass after one growing season. Inundation time, salinity, sulfides, and redox potential were measured concurrently. As predicted, increasing inundation reduced biomass of the species commonly found at higher marsh elevations, with little effect on the species found along channel margins. The presence of neighbors reduced total biomass of both species, particularly at the highest elevation; facilitation did not occur at any elevation. Contrary to predictions, we documented the competitive superiority of the stress tolerator under increased inundation, which was not predicted by the stress gradient hypothesis. Multifactor manipulation experiments addressing plant response to accelerated climate change are integral to creating a more realistic, valuable, and needed assessment of potential ecosystem response. Our results point to the important and unpredicted synergies between physical stressors, which are predicted to increase in intensity with climate change, and competitive forces on biomass as stresses increase. We simulated sea‐level rise to test the effect of increased inundation and biotic interactions on plant growth of two wetland species to examine whether climate change impacts could alter competition/stress tolerance trade‐offs or resulting shifts in distributions. Increasing inundation reduced biomass of the species commonly found at higher marsh elevations, with little effect on the species found along channel margins, and we documented the competitive superiority of the stress tolerator under increased inundation, which was not predicted by the stress/competition trade‐off model. Our results point to the important and unpredictable synergies between stressors such as inundation and salinity, which are predicted to increase in intensity with climate change, and competitive forces on biomass as stresses increase.</abstract><cop>England</cop><pub>John Wiley & Sons, Inc</pub><pmid>28303196</pmid><doi>10.1002/ece3.2758</doi><tpages>10</tpages><orcidid>https://orcid.org/0000-0001-8565-3825</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Biomass Climate change Community structure competition Ecosystem assessment Ecosystems Elevation Environmental changes Environmental impact Estuaries Estuarine environments facilitation Hypotheses Original Research Predictions Redox potential Salinity Salinity effects Schoenoplectus Schoenoplectus acutus Schoenoplectus americanus Sea level Sea level rise Species Stress Stresses tidal wetlands Wetlands
title	Can community structure track sea‐level rise? Stress and competitive controls in tidal wetlands
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