Your search keyword '"Bluhm, Sarah L."' showing total 4 results

1. Protura are unique: first evidence of specialized feeding on ectomycorrhizal fungi in soil invertebrates

Author

Bluhm, Sarah L., Potapov, Anton M., Shrubovych, Julia, Ammerschubert, Silke, Polle, Andrea, and Scheu, Stefan

Published

2019

2. Feeding habits and multifunctional classification of soil‐associated consumers from protists to vertebrates.

Author

Potapov, Anton M., Beaulieu, Frédéric, Birkhofer, Klaus, Bluhm, Sarah L., Degtyarev, Maxim I., Devetter, Miloslav, Goncharov, Anton A., Gongalsky, Konstantin B., Klarner, Bernhard, Korobushkin, Daniil I., Liebke, Dana F., Maraun, Mark, Mc Donnell, Rory J., Pollierer, Melanie M., Schaefer, Ina, Shrubovych, Julia, Semenyuk, Irina I., Sendra, Alberto, Tuma, Jiri, and Tůmová, Michala

Subjects

SOIL ecology, FOOD chains, SOIL biology, PROTISTA, FOOD preferences, SOIL classification

Abstract

Soil organisms drive major ecosystem functions by mineralising carbon and releasing nutrients during decomposition processes, which supports plant growth, aboveground biodiversity and, ultimately, human nutrition. Soil ecologists often operate with functional groups to infer the effects of individual taxa on ecosystem functions and services. Simultaneous assessment of the functional roles of multiple taxa is possible using food‐web reconstructions, but our knowledge of the feeding habits of many taxa is insufficient and often based on limited evidence. Over the last two decades, molecular, biochemical and isotopic tools have improved our understanding of the feeding habits of various soil organisms, yet this knowledge is still to be synthesised into a common functional framework. Here, we provide a comprehensive review of the feeding habits of consumers in soil, including protists, micro‐, meso‐ and macrofauna (invertebrates), and soil‐associated vertebrates. We have integrated existing functional group classifications with findings gained with novel methods and compiled an overarching classification across taxa focusing on key universal traits such as food resource preferences, body masses, microhabitat specialisation, protection and hunting mechanisms. Our summary highlights various strands of evidence that many functional groups commonly used in soil ecology and food‐web models are feeding on multiple types of food resources. In many cases, omnivory is observed down to the species level of taxonomic resolution, challenging realism of traditional soil food‐web models based on distinct resource‐based energy channels. Novel methods, such as stable isotope, fatty acid and DNA gut content analyses, have revealed previously hidden facets of trophic relationships of soil consumers, such as food assimilation, multichannel feeding across trophic levels, hidden trophic niche differentiation and the importance of alternative food/prey, as well as energy transfers across ecosystem compartments. Wider adoption of such tools and the development of open interoperable platforms that assemble morphological, ecological and trophic data as traits of soil taxa will enable the refinement and expansion of the multifunctional classification of consumers in soil. The compiled multifunctional classification of soil‐associated consumers will serve as a reference for ecologists working with biodiversity changes and biodiversity–ecosystem functioning relationships, making soil food‐web research more accessible and reproducible. [ABSTRACT FROM AUTHOR]

Published

2022

3. Shift in trophic niches of soil microarthropods with conversion of tropical rainforest into plantations as indicated by stable isotopes (15N, 13C)

Author

Krause, Alena, Sandmann, Dorothee, Bluhm, Sarah L., Ermilov, Sergey, Widyastuti, Rahayu, Haneda, Noor Farikhah, Scheu, Stefan, and Maraun, Mark

Subjects

Composite Particles, Atoms, Rainforest, Arthropoda, Polymers, Science, Materials Science, Predation, Jungles, Forests, Ecosystems, Soil, Isotopes, Animals, Oil Palm, Particle Physics, Materials, Arthropods, Rubber, Rainforests, Mites, Stable isotopes, Oil palm, Carbon Isotopes, Tropical Climate, Ecology, Nitrogen Isotopes, Physics, Stable Isotopes, Ecology and Environmental Sciences, Organisms, Biology and Life Sciences, Eukaryota, Plants, Polymer Chemistry, Terrestrial Environments, Invertebrates, Trophic Interactions, Chemistry, Macromolecules, Elastomers, Community Ecology, Physical Sciences, Medicine, Research Article

Abstract

Land-use change is threatening biodiversity worldwide, affecting above and below ground animal communities by altering their trophic niches. However, shifts in trophic niches with changes in land use are little studied and this applies in particular to belowground animals. Oribatid mites are among the most abundant soil animals, involved in decomposition processes and nutrient cycling. We analyzed shifts in trophic niches of six soil-living oribatid mite species with the conversion of lowland secondary rainforest into plantation systems of different land-use intensity (jungle rubber, rubber and oil palm monoculture plantation) in two regions of southwest Sumatra, Indonesia. We measured stable isotope ratios (13C/12C and 15N/14N) of single oribatid mite individuals and calculated shifts in stable isotope niches with changes in land use. Significant changes in stable isotope ratios in three of the six studied oribatid mite species indicated that these species shift their trophic niches with changes in land use. The trophic shift was either due to changes in trophic level (δ15N values), to changes in the use of basal resources (δ13C values) or to changes in both. The trophic shift generally was most pronounced between more natural systems (rainforest and jungle rubber) on one side and monoculture plantations systems (rubber and oil palm plantations) on the other, reflecting that the shifts were related to land-use intensity. Although trophic niches of the other three studied species did not differ significantly between land-use systems they followed a similar trend. Overall, the results suggest that colonization of very different ecosystems such as rainforest and intensively managed monoculture plantations by oribatid mite species likely is related to their ability to shift their trophic niches, i.e. to trophic plasticity. Open-Access-Publikationsfonds 2019 peerReviewed

Published

2019

4. Shift in trophic niches of soil microarthropods with conversion of tropical rainforest into plantations as indicated by stable isotopes (15N, 13C).

Author

Krause, Alena, Sandmann, Dorothee, Bluhm, Sarah L., Ermilov, Sergey, Widyastuti, Rahayu, Haneda, Noor Farikhah, Scheu, Stefan, and Maraun, Mark

Subjects

RAIN forests, STABLE isotopes, PLANTATIONS, LAND use, SOIL animals, TIRE recycling

Abstract

Land-use change is threatening biodiversity worldwide, affecting above and below ground animal communities by altering their trophic niches. However, shifts in trophic niches with changes in land use are little studied and this applies in particular to belowground animals. Oribatid mites are among the most abundant soil animals, involved in decomposition processes and nutrient cycling. We analyzed shifts in trophic niches of six soil-living oribatid mite species with the conversion of lowland secondary rainforest into plantation systems of different land-use intensity (jungle rubber, rubber and oil palm monoculture plantation) in two regions of southwest Sumatra, Indonesia. We measured stable isotope ratios (13C/12C and 15N/14N) of single oribatid mite individuals and calculated shifts in stable isotope niches with changes in land use. Significant changes in stable isotope ratios in three of the six studied oribatid mite species indicated that these species shift their trophic niches with changes in land use. The trophic shift was either due to changes in trophic level (δ15N values), to changes in the use of basal resources (δ13C values) or to changes in both. The trophic shift generally was most pronounced between more natural systems (rainforest and jungle rubber) on one side and monoculture plantations systems (rubber and oil palm plantations) on the other, reflecting that the shifts were related to land-use intensity. Although trophic niches of the other three studied species did not differ significantly between land-use systems they followed a similar trend. Overall, the results suggest that colonization of very different ecosystems such as rainforest and intensively managed monoculture plantations by oribatid mite species likely is related to their ability to shift their trophic niches, i.e. to trophic plasticity. [ABSTRACT FROM AUTHOR]

Published

2019