A multi-disciplinarily designed mesocosm to address the complex flow-sediment-ecology tripartite relationship on the microscale

Holger Schmidt; Moritz Thom; Kerstin Matthies; Sebastian Behrens; Ursula Obst; Silke Wieprecht; Sabine Ulrike Gerbersdorf

doi:10.1186/s12302-014-0037-y

A multi-disciplinarily designed mesocosm to address the complex flow-sediment-ecology tripartite relationship on the microscale

Holger Schmidt, Moritz Thom, Kerstin Matthies, Sebastian Behrens, Ursula Obst, Silke Wieprecht, Sabine Ulrike Gerbersdorf

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Background: The stabilization of fine sediments via biofilms (‘biostabilization’) has various economic and ecological implications but is presently unaddressed within lotic waters. To investigate natural biofilm growth and functionality in freshwater sediments under controlled boundary conditions, a unique mesocosm was constructed that combines established know-how from engineering and natural sciences and consists of six straight flumes. To test the comparability of biofilm growth within one flume and between the flumes, extracellular polymeric substances (EPSs), microbial biomass and microbial community composition were closely monitored over time and space as well as in relation to biofilm adhesiveness (proxy for biostabilization). Results: Most importantly, biofilm development and biostabilization capacity revealed no significant differences within flume regions or between the flumes and the biofilms significantly stabilized the substratum as compared to abiotic controls. However, interesting temporal successions in biofilm growth phases became visible in shifting abundance and diversity of bacteria and microalgae resulting in varying EPS secretion and biostabilization. Conclusions: These findings demonstrated the importance of biostabilization for fine sediment dynamics in freshwaters. Secondly, this unique setup allows comparable biofilm growth under controlled environmental conditions, an important requisite for future research on the ecological significance and impact of biostabilization for ecosystem functioning at varying environmental scenarios.

Original language	English (US)
Journal	Environmental Sciences Europe
Volume	27
Issue number	1
DOIs	https://doi.org/10.1186/s12302-014-0037-y
State	Published - 2015

Bibliographical note

Funding Information:
The authors are grateful to the DFG (Deutsche Forschungsgemeinschaft) for financing the project ‘Ecosystem Engineering: Sediment entrainment and flocculation mediated by microbial produced extracellular polymeric substances (EPS)’ (GZ: GE 1932/3-1). We thank for the excellent support of the molecular analyses at the Institute of Functional Interfaces, Karlsruhe Institute of Technology (KIT) (Prof. U. Obst) and at the Centre for Applied Geosciences (ZAG), University Tübingen (Prof. A. Kappler). The authors much appreciate the cooperation with Dr. M. Schweikert, Institute of Zoology, University Stuttgart to get access to the Microscopic Facility.

Publisher Copyright:
© 2015, Schmidt et al.

Keywords

Adhesion
Biofilm
Biostabilization
DGGE
Diatoms
Extracellular polymeric substances (EPSs)
Flume
MagPI
Sediment stability

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title = "A multi-disciplinarily designed mesocosm to address the complex flow-sediment-ecology tripartite relationship on the microscale",

abstract = "Background: The stabilization of fine sediments via biofilms ({\textquoteleft}biostabilization{\textquoteright}) has various economic and ecological implications but is presently unaddressed within lotic waters. To investigate natural biofilm growth and functionality in freshwater sediments under controlled boundary conditions, a unique mesocosm was constructed that combines established know-how from engineering and natural sciences and consists of six straight flumes. To test the comparability of biofilm growth within one flume and between the flumes, extracellular polymeric substances (EPSs), microbial biomass and microbial community composition were closely monitored over time and space as well as in relation to biofilm adhesiveness (proxy for biostabilization). Results: Most importantly, biofilm development and biostabilization capacity revealed no significant differences within flume regions or between the flumes and the biofilms significantly stabilized the substratum as compared to abiotic controls. However, interesting temporal successions in biofilm growth phases became visible in shifting abundance and diversity of bacteria and microalgae resulting in varying EPS secretion and biostabilization. Conclusions: These findings demonstrated the importance of biostabilization for fine sediment dynamics in freshwaters. Secondly, this unique setup allows comparable biofilm growth under controlled environmental conditions, an important requisite for future research on the ecological significance and impact of biostabilization for ecosystem functioning at varying environmental scenarios.",

keywords = "Adhesion, Biofilm, Biostabilization, DGGE, Diatoms, Extracellular polymeric substances (EPSs), Flume, MagPI, Sediment stability",

author = "Holger Schmidt and Moritz Thom and Kerstin Matthies and Sebastian Behrens and Ursula Obst and Silke Wieprecht and Gerbersdorf, {Sabine Ulrike}",

note = "Funding Information: The authors are grateful to the DFG (Deutsche Forschungsgemeinschaft) for financing the project {\textquoteleft}Ecosystem Engineering: Sediment entrainment and flocculation mediated by microbial produced extracellular polymeric substances (EPS){\textquoteright} (GZ: GE 1932/3-1). We thank for the excellent support of the molecular analyses at the Institute of Functional Interfaces, Karlsruhe Institute of Technology (KIT) (Prof. U. Obst) and at the Centre for Applied Geosciences (ZAG), University T{\"u}bingen (Prof. A. Kappler). The authors much appreciate the cooperation with Dr. M. Schweikert, Institute of Zoology, University Stuttgart to get access to the Microscopic Facility. Publisher Copyright: {\textcopyright} 2015, Schmidt et al.",

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doi = "10.1186/s12302-014-0037-y",

language = "English (US)",

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AU - Schmidt, Holger

AU - Thom, Moritz

AU - Matthies, Kerstin

AU - Behrens, Sebastian

AU - Obst, Ursula

AU - Wieprecht, Silke

AU - Gerbersdorf, Sabine Ulrike

N1 - Funding Information: The authors are grateful to the DFG (Deutsche Forschungsgemeinschaft) for financing the project ‘Ecosystem Engineering: Sediment entrainment and flocculation mediated by microbial produced extracellular polymeric substances (EPS)’ (GZ: GE 1932/3-1). We thank for the excellent support of the molecular analyses at the Institute of Functional Interfaces, Karlsruhe Institute of Technology (KIT) (Prof. U. Obst) and at the Centre for Applied Geosciences (ZAG), University Tübingen (Prof. A. Kappler). The authors much appreciate the cooperation with Dr. M. Schweikert, Institute of Zoology, University Stuttgart to get access to the Microscopic Facility. Publisher Copyright: © 2015, Schmidt et al.

PY - 2015

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N2 - Background: The stabilization of fine sediments via biofilms (‘biostabilization’) has various economic and ecological implications but is presently unaddressed within lotic waters. To investigate natural biofilm growth and functionality in freshwater sediments under controlled boundary conditions, a unique mesocosm was constructed that combines established know-how from engineering and natural sciences and consists of six straight flumes. To test the comparability of biofilm growth within one flume and between the flumes, extracellular polymeric substances (EPSs), microbial biomass and microbial community composition were closely monitored over time and space as well as in relation to biofilm adhesiveness (proxy for biostabilization). Results: Most importantly, biofilm development and biostabilization capacity revealed no significant differences within flume regions or between the flumes and the biofilms significantly stabilized the substratum as compared to abiotic controls. However, interesting temporal successions in biofilm growth phases became visible in shifting abundance and diversity of bacteria and microalgae resulting in varying EPS secretion and biostabilization. Conclusions: These findings demonstrated the importance of biostabilization for fine sediment dynamics in freshwaters. Secondly, this unique setup allows comparable biofilm growth under controlled environmental conditions, an important requisite for future research on the ecological significance and impact of biostabilization for ecosystem functioning at varying environmental scenarios.

AB - Background: The stabilization of fine sediments via biofilms (‘biostabilization’) has various economic and ecological implications but is presently unaddressed within lotic waters. To investigate natural biofilm growth and functionality in freshwater sediments under controlled boundary conditions, a unique mesocosm was constructed that combines established know-how from engineering and natural sciences and consists of six straight flumes. To test the comparability of biofilm growth within one flume and between the flumes, extracellular polymeric substances (EPSs), microbial biomass and microbial community composition were closely monitored over time and space as well as in relation to biofilm adhesiveness (proxy for biostabilization). Results: Most importantly, biofilm development and biostabilization capacity revealed no significant differences within flume regions or between the flumes and the biofilms significantly stabilized the substratum as compared to abiotic controls. However, interesting temporal successions in biofilm growth phases became visible in shifting abundance and diversity of bacteria and microalgae resulting in varying EPS secretion and biostabilization. Conclusions: These findings demonstrated the importance of biostabilization for fine sediment dynamics in freshwaters. Secondly, this unique setup allows comparable biofilm growth under controlled environmental conditions, an important requisite for future research on the ecological significance and impact of biostabilization for ecosystem functioning at varying environmental scenarios.

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KW - DGGE

KW - Diatoms

KW - Extracellular polymeric substances (EPSs)

KW - Flume

KW - MagPI

KW - Sediment stability

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ER -

A multi-disciplinarily designed mesocosm to address the complex flow-sediment-ecology tripartite relationship on the microscale

Abstract

Bibliographical note

Keywords

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