TY - JOUR
T1 - Long-term multidecadal data from a prairie-pothole wetland complex reveal controls on aquatic-macroinvertebrate communities
AU - McLean, Kyle I.
AU - Mushet, David M.
AU - Newton, Wesley E.
AU - Sweetman, Jon N.
N1 - Funding Information:
Our manuscript would have not been possible if not for the pioneering efforts of George Swanson (deceased) and Ned Euliss, Jr. (USGS retired) in starting and maintaining the long-term data collection efforts at the Cottonwood Lake Study Area. We also thank Ned Euliss, Jr. and Clint R. V. Otto for the significant insights they provided during the early stages of our work. Additionally, we thank Mark Wiltermuth and two anonymous reviewers for their reviews of earlier drafts of this manuscript. Funding for our research was provided through the U.S Geological Survey's Land Change Science Research and Development Program. Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government.
Funding Information:
Our manuscript would have not been possible if not for the pioneering efforts of George Swanson (deceased) and Ned Euliss, Jr. (USGS retired) in starting and maintaining the long-term data collection efforts at the Cottonwood Lake Study Area. We also thank Ned Euliss, Jr. and Clint R. V. Otto for the significant insights they provided during the early stages of our work. Additionally, we thank Mark Wiltermuth and two anonymous reviewers for their reviews of earlier drafts of this manuscript. Funding for our research was provided through the U.S Geological Survey’s Land Change Science Research and Development Program. Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government.
Publisher Copyright:
© 2021
PY - 2021/7
Y1 - 2021/7
N2 - Interactions between climate and hydrogeologic settings contribute to the hydrologic and chemical variability among depressional wetlands, which influences their aquatic communities. These interactions and resulting variability have led to inconsistent results in terms of identifying reliable predictors of aquatic-macroinvertebrate community composition for depressional wetlands. This is especially true in the Prairie Pothole Region of North America where, in addition to pronounced climate variability, studies are often confounded by fish introductions. We used environmental monitoring data collected over a 24-year period from a complex of sixteen depressional wetlands and structural equation modeling techniques that incorporated theoretical and empirical relationships outlined in the Wetland Continuum to identify key environmental (climate and hydrogeologic setting) and biotic (competition and predation) drivers of aquatic-macroinvertebrate community composition for prairie-pothole wetlands. Uplands in the study area were primarily native prairie, thus, embedded wetlands were impacted minimally by agricultural influences. Additionally, study wetlands were predominately fishless. In the absence of the overwhelming influence of fishes, major drivers influencing aquatic-macroinvertebrate communities were revealed through the use of data spanning multidecadal-long climate cycles. We found variables related to the placement of wetlands along axes of the Wetland Continuum, e.g., hydrogeologic setting (relative wetland elevation) and hydroclimatic setting (proportion of wetland ponded), to be influential drivers of within-wetland habitat characteristics, such as the proportion of open-water area, which in turn was the strongest predictor of macroinvertebrate community composition. In contrast, predatory invertebrate and salamander abundance and non-predatory invertebrate biomass (i.e., predation and competition) were found to have minimal influence on community composition.
AB - Interactions between climate and hydrogeologic settings contribute to the hydrologic and chemical variability among depressional wetlands, which influences their aquatic communities. These interactions and resulting variability have led to inconsistent results in terms of identifying reliable predictors of aquatic-macroinvertebrate community composition for depressional wetlands. This is especially true in the Prairie Pothole Region of North America where, in addition to pronounced climate variability, studies are often confounded by fish introductions. We used environmental monitoring data collected over a 24-year period from a complex of sixteen depressional wetlands and structural equation modeling techniques that incorporated theoretical and empirical relationships outlined in the Wetland Continuum to identify key environmental (climate and hydrogeologic setting) and biotic (competition and predation) drivers of aquatic-macroinvertebrate community composition for prairie-pothole wetlands. Uplands in the study area were primarily native prairie, thus, embedded wetlands were impacted minimally by agricultural influences. Additionally, study wetlands were predominately fishless. In the absence of the overwhelming influence of fishes, major drivers influencing aquatic-macroinvertebrate communities were revealed through the use of data spanning multidecadal-long climate cycles. We found variables related to the placement of wetlands along axes of the Wetland Continuum, e.g., hydrogeologic setting (relative wetland elevation) and hydroclimatic setting (proportion of wetland ponded), to be influential drivers of within-wetland habitat characteristics, such as the proportion of open-water area, which in turn was the strongest predictor of macroinvertebrate community composition. In contrast, predatory invertebrate and salamander abundance and non-predatory invertebrate biomass (i.e., predation and competition) were found to have minimal influence on community composition.
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U2 - 10.1016/j.ecolind.2021.107678
DO - 10.1016/j.ecolind.2021.107678
M3 - Article
AN - SCOPUS:85104115553
SN - 1470-160X
VL - 126
JO - Ecological Indicators
JF - Ecological Indicators
M1 - 107678
ER -