Large and interacting effects of temperature and nutrient addition on stratified microbial ecosystems in a small, replicated, and liquid‐dominated Winogradsky column approach
Abstract Aquatic ecosystems are often stratified, with cyanobacteria in oxic layers and phototrophic sulfur bacteria in anoxic zones. Changes in stratification caused by the global environmental change are an ongoing concern. Increasing understanding of how such aerobic and anaerobic microbial commu...
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Wiley
2021-06-01
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| Series: | MicrobiologyOpen |
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| Online Access: | https://doi.org/10.1002/mbo3.1189 |
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doaj-b8e0312bc31e4e7c812bd4f0b52f80682021-06-28T07:05:59ZengWileyMicrobiologyOpen2045-88272021-06-01103n/an/a10.1002/mbo3.1189Large and interacting effects of temperature and nutrient addition on stratified microbial ecosystems in a small, replicated, and liquid‐dominated Winogradsky column approachMarcel Suleiman0Yves Choffat1Uriah Daugaard2Owen L. Petchey3Department of Evolutionary Biology and Environmental Studies University of Zurich Zurich SwitzerlandDepartment of Evolutionary Biology and Environmental Studies University of Zurich Zurich SwitzerlandDepartment of Evolutionary Biology and Environmental Studies University of Zurich Zurich SwitzerlandDepartment of Evolutionary Biology and Environmental Studies University of Zurich Zurich SwitzerlandAbstract Aquatic ecosystems are often stratified, with cyanobacteria in oxic layers and phototrophic sulfur bacteria in anoxic zones. Changes in stratification caused by the global environmental change are an ongoing concern. Increasing understanding of how such aerobic and anaerobic microbial communities, and associated abiotic conditions, respond to multifarious environmental changes is an important endeavor in microbial ecology. Insights can come from observational and experimental studies of naturally occurring stratified aquatic ecosystems, theoretical models of ecological processes, and experimental studies of replicated microbial communities in the laboratory. Here, we demonstrate a laboratory‐based approach with small, replicated, and liquid‐dominated Winogradsky columns, with distinct oxic/anoxic strata in a highly replicable manner. Our objective was to apply simultaneous global change scenarios (temperature, nutrient addition) on this micro‐ecosystem to report how the microbial communities (full‐length 16S rRNA gene seq.) and the abiotic conditions (O2, H2S, TOC) of the oxic/anoxic layer responded to these environmental changes. The composition of the strongly stratified microbial communities was greatly affected by temperature and by the interaction of temperature and nutrient addition, demonstrating the need of investigating global change treatments simultaneously. Especially phototrophic sulfur bacteria dominated the water column at higher temperatures and may indicate the presence of alternative stable states. We show that the establishment of such a micro‐ecosystem has the potential to test global change scenarios in stratified eutrophic limnic systems.https://doi.org/10.1002/mbo3.1189anaerobescyanobacteriaglobal changeoxygenphototrophic sulfur bacteria |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Marcel Suleiman Yves Choffat Uriah Daugaard Owen L. Petchey |
| spellingShingle |
Marcel Suleiman Yves Choffat Uriah Daugaard Owen L. Petchey Large and interacting effects of temperature and nutrient addition on stratified microbial ecosystems in a small, replicated, and liquid‐dominated Winogradsky column approach MicrobiologyOpen anaerobes cyanobacteria global change oxygen phototrophic sulfur bacteria |
| author_facet |
Marcel Suleiman Yves Choffat Uriah Daugaard Owen L. Petchey |
| author_sort |
Marcel Suleiman |
| title |
Large and interacting effects of temperature and nutrient addition on stratified microbial ecosystems in a small, replicated, and liquid‐dominated Winogradsky column approach |
| title_short |
Large and interacting effects of temperature and nutrient addition on stratified microbial ecosystems in a small, replicated, and liquid‐dominated Winogradsky column approach |
| title_full |
Large and interacting effects of temperature and nutrient addition on stratified microbial ecosystems in a small, replicated, and liquid‐dominated Winogradsky column approach |
| title_fullStr |
Large and interacting effects of temperature and nutrient addition on stratified microbial ecosystems in a small, replicated, and liquid‐dominated Winogradsky column approach |
| title_full_unstemmed |
Large and interacting effects of temperature and nutrient addition on stratified microbial ecosystems in a small, replicated, and liquid‐dominated Winogradsky column approach |
| title_sort |
large and interacting effects of temperature and nutrient addition on stratified microbial ecosystems in a small, replicated, and liquid‐dominated winogradsky column approach |
| publisher |
Wiley |
| series |
MicrobiologyOpen |
| issn |
2045-8827 |
| publishDate |
2021-06-01 |
| description |
Abstract Aquatic ecosystems are often stratified, with cyanobacteria in oxic layers and phototrophic sulfur bacteria in anoxic zones. Changes in stratification caused by the global environmental change are an ongoing concern. Increasing understanding of how such aerobic and anaerobic microbial communities, and associated abiotic conditions, respond to multifarious environmental changes is an important endeavor in microbial ecology. Insights can come from observational and experimental studies of naturally occurring stratified aquatic ecosystems, theoretical models of ecological processes, and experimental studies of replicated microbial communities in the laboratory. Here, we demonstrate a laboratory‐based approach with small, replicated, and liquid‐dominated Winogradsky columns, with distinct oxic/anoxic strata in a highly replicable manner. Our objective was to apply simultaneous global change scenarios (temperature, nutrient addition) on this micro‐ecosystem to report how the microbial communities (full‐length 16S rRNA gene seq.) and the abiotic conditions (O2, H2S, TOC) of the oxic/anoxic layer responded to these environmental changes. The composition of the strongly stratified microbial communities was greatly affected by temperature and by the interaction of temperature and nutrient addition, demonstrating the need of investigating global change treatments simultaneously. Especially phototrophic sulfur bacteria dominated the water column at higher temperatures and may indicate the presence of alternative stable states. We show that the establishment of such a micro‐ecosystem has the potential to test global change scenarios in stratified eutrophic limnic systems. |
| topic |
anaerobes cyanobacteria global change oxygen phototrophic sulfur bacteria |
| url |
https://doi.org/10.1002/mbo3.1189 |
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