Publikation: Design and construction of 3D printed devices to investigate active and passive bacterial dispersal on hydrated surfaces
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Datum
2022
Autor:innen
Kuhn, Thierry
Buffi, Matteo
Bindschedler, Saskia
Chain, Patrick S.
Gonzalez, Diego
Stanley, Claire E.
Wick, Lukas Y.
Junier, Pilar
Herausgeber:innen
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Swiss National Science Foundation: 180145
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Open Access-Veröffentlichung
Open Access Gold
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Core Facility der Universität Konstanz
Titel in einer weiteren Sprache
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Published
Erschienen in
BMC Biology (incorporating Journal of Biology). Springer. 2022, 20(1), 203. eISSN 1741-7007. Verfügbar unter: doi: 10.1186/s12915-022-01406-z
Zusammenfassung
Background To disperse in water-unsaturated environments, such as the soil, bacteria rely on the availability and structure of water films forming on biotic and abiotic surfaces, and, especially, along fungal mycelia. Dispersal along such “fungal highways” may be driven both by mycelial physical properties and by interactions between bacteria and fungi. However, we still do not have a way to disentangle the biotic and abiotic elements.
Results We designed and 3D printed two devices establishing stable liquid films that support bacteria dispersal in the absence of biotic interactions. The thickness of the liquid film determined the presence of hydraulic flow capable of transporting non-motile cells. In the absence of flow, only motile cells can disperse in the presence of an energy source. Non-motile cells could not disperse autonomously without flow but dispersed as “hitchhikers” when co-inoculated with motile cells.
Conclusions The 3D printed devices can be used as an abiotic control to study bacterial dispersal on hydrated surfaces, such as plant roots and fungal hyphae networks in the soil. By teasing apart the abiotic and biotic dimensions, these 3D printed devices will stimulate further research on microbial dispersal in soil and other water-unsaturated environments.
Zusammenfassung in einer weiteren Sprache
Fachgebiet (DDC)
570 Biowissenschaften, Biologie
Schlagwörter
3D printing, Bacterial motility, Bacterial-fungal interactions, Fungal highways, Bacterial dispersal, Hitchhiking dispersal
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KUHN, Thierry, Matteo BUFFI, Saskia BINDSCHEDLER, Patrick S. CHAIN, Diego GONZALEZ, Claire E. STANLEY, Lukas Y. WICK, Pilar JUNIER, Xiang-Yi LI RICHTER, 2022. Design and construction of 3D printed devices to investigate active and passive bacterial dispersal on hydrated surfaces. In: BMC Biology (incorporating Journal of Biology). Springer. 2022, 20(1), 203. eISSN 1741-7007. Verfügbar unter: doi: 10.1186/s12915-022-01406-zBibTex
@article{Kuhn2022-09-14Desig-73112,
title={Design and construction of 3D printed devices to investigate active and passive bacterial dispersal on hydrated surfaces},
year={2022},
doi={10.1186/s12915-022-01406-z},
number={1},
volume={20},
journal={BMC Biology (incorporating Journal of Biology)},
author={Kuhn, Thierry and Buffi, Matteo and Bindschedler, Saskia and Chain, Patrick S. and Gonzalez, Diego and Stanley, Claire E. and Wick, Lukas Y. and Junier, Pilar and Li Richter, Xiang-Yi},
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<dcterms:abstract>Background
To disperse in water-unsaturated environments, such as the soil, bacteria rely on the availability and structure of water films forming on biotic and abiotic surfaces, and, especially, along fungal mycelia. Dispersal along such “fungal highways” may be driven both by mycelial physical properties and by interactions between bacteria and fungi. However, we still do not have a way to disentangle the biotic and abiotic elements.
Results
We designed and 3D printed two devices establishing stable liquid films that support bacteria dispersal in the absence of biotic interactions. The thickness of the liquid film determined the presence of hydraulic flow capable of transporting non-motile cells. In the absence of flow, only motile cells can disperse in the presence of an energy source. Non-motile cells could not disperse autonomously without flow but dispersed as “hitchhikers” when co-inoculated with motile cells.
Conclusions
The 3D printed devices can be used as an abiotic control to study bacterial dispersal on hydrated surfaces, such as plant roots and fungal hyphae networks in the soil. By teasing apart the abiotic and biotic dimensions, these 3D printed devices will stimulate further research on microbial dispersal in soil and other water-unsaturated environments.</dcterms:abstract>
<dc:contributor>Wick, Lukas Y.</dc:contributor>
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<dc:creator>Gonzalez, Diego</dc:creator>
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