Habitat Complexity in Aquatic Microcosms Affects Processes Driven by Detritivores

Habitat complexity can influence predation rates (e.g. by providing refuge) but other ecosystem processes and species interactions might also be modulated by the properties of habitat structure. Here, we focussed on how complexity of artificial habitat (plastic plants), in microcosms, influenced sho...

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Veröffentlicht in:	PloS one 2016-11, Vol.11 (11), p.e0165065-e0165065
Hauptverfasser:	Flores, Lorea, Bailey, R A, Elosegi, Arturo, Larrañaga, Aitor, Reiss, Julia
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis Animals Aquatic ecosystems Aquatic habitats Aquatic Organisms - physiology Aquatic plants Biodiversity Biodiversity and Ecology Biology and Life Sciences Complexity Decomposition Detritivores Ecological monitoring Ecology Ecology and Environmental Sciences Ecosystem Ecosystem biology Ecosystems Energy flow Environmental Sciences Experimental design Experiments Food Chain Foraging behavior Fractals Habitats Influence Laboratories Life sciences Mathematical models Microcosms Organic matter Particulate matter pH effects Physical Sciences Plant biology Plant Leaves - physiology Plastics Predation Predatory Behavior - physiology Research and Analysis Methods Restoration Species Statistical analysis Statistical models Trends
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creator	Flores, Lorea Bailey, R A Elosegi, Arturo Larrañaga, Aitor Reiss, Julia
description	Habitat complexity can influence predation rates (e.g. by providing refuge) but other ecosystem processes and species interactions might also be modulated by the properties of habitat structure. Here, we focussed on how complexity of artificial habitat (plastic plants), in microcosms, influenced short-term processes driven by three aquatic detritivores. The effects of habitat complexity on leaf decomposition, production of fine organic matter and pH levels were explored by measuring complexity in three ways: 1. as the presence vs. absence of habitat structure; 2. as the amount of structure (3 or 4.5 g of plastic plants); and 3. as the spatial configuration of structures (measured as fractal dimension). The experiment also addressed potential interactions among the consumers by running all possible species combinations. In the experimental microcosms, habitat complexity influenced how species performed, especially when comparing structure present vs. structure absent. Treatments with structure showed higher fine particulate matter production and lower pH compared to treatments without structures and this was probably due to higher digestion and respiration when structures were present. When we explored the effects of the different complexity levels, we found that the amount of structure added explained more than the fractal dimension of the structures. We give a detailed overview of the experimental design, statistical models and R codes, because our statistical analysis can be applied to other study systems (and disciplines such as restoration ecology). We further make suggestions of how to optimise statistical power when artificially assembling, and analysing, 'habitat complexity' by not confounding complexity with the amount of structure added. In summary, this study highlights the importance of habitat complexity for energy flow and the maintenance of ecosystem processes in aquatic ecosystems.
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Treatments with structure showed higher fine particulate matter production and lower pH compared to treatments without structures and this was probably due to higher digestion and respiration when structures were present. When we explored the effects of the different complexity levels, we found that the amount of structure added explained more than the fractal dimension of the structures. We give a detailed overview of the experimental design, statistical models and R codes, because our statistical analysis can be applied to other study systems (and disciplines such as restoration ecology). We further make suggestions of how to optimise statistical power when artificially assembling, and analysing, 'habitat complexity' by not confounding complexity with the amount of structure added. 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Treatments with structure showed higher fine particulate matter production and lower pH compared to treatments without structures and this was probably due to higher digestion and respiration when structures were present. When we explored the effects of the different complexity levels, we found that the amount of structure added explained more than the fractal dimension of the structures. We give a detailed overview of the experimental design, statistical models and R codes, because our statistical analysis can be applied to other study systems (and disciplines such as restoration ecology). We further make suggestions of how to optimise statistical power when artificially assembling, and analysing, 'habitat complexity' by not confounding complexity with the amount of structure added. 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subjects	Analysis Animals Aquatic ecosystems Aquatic habitats Aquatic Organisms - physiology Aquatic plants Biodiversity Biodiversity and Ecology Biology and Life Sciences Complexity Decomposition Detritivores Ecological monitoring Ecology Ecology and Environmental Sciences Ecosystem Ecosystem biology Ecosystems Energy flow Environmental Sciences Experimental design Experiments Food Chain Foraging behavior Fractals Habitats Influence Laboratories Life sciences Mathematical models Microcosms Organic matter Particulate matter pH effects Physical Sciences Plant biology Plant Leaves - physiology Plastics Predation Predatory Behavior - physiology Research and Analysis Methods Restoration Species Statistical analysis Statistical models Trends
title	Habitat Complexity in Aquatic Microcosms Affects Processes Driven by Detritivores
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