Physically triggered morphology changes in a novel Acremonium isolate cultivated in precisely engineered microfabricated environments
Fungi are strongly affected by their physical environment. Microfabrication offers the possibility of creating new culture environments and ecosystems with defined characteristics. Here, we report the isolation of a novel member of the fungal genus Acremonium using a microengineered cultivation chip. This isolate was unusual in that it organizes into macroscopic structures when initially cultivated within microwells with a porous aluminum oxide (PAO) base. These "templated mycelial bundles" (TMB) were formed from masses of parallel hyphae with side branching suppressed. TMB were highly hydrated, facilitating the passive movement of solutes along the bundle. By using a range of culture chips, it was deduced that the critical factors in triggering the TMB were growth in microwells from 50 to 300 μm in diameter with a PAO base. Cultivation experiments, using spores and pigments as tracking agents, indicate that bulk growth of the TMB occurs at the base. TMB morphology is highly coherent and is maintained after growing out of the microwells. TMB can explore their environment by developing unbundled lateral hyphae; TMB only followed if nutrients were available. Because of the ease of fabricating numerous microstructures, we suggest this is a productive approach for exploring morphology and growth in multicellular microorganisms and microbial communities.
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| Format: | Article/Letter to editor biblioteca |
| Language: | English |
| Subjects: | Cultivation chips, Fungi, Growth on surfaces, Mycelial organization, Simulated environments, |
| Online Access: | https://research.wur.nl/en/publications/physically-triggered-morphology-changes-in-a-novel-acremonium-iso |
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dig-wur-nl-wurpubs-5244002025-01-17 Catón, Laura Yurkov, Andrey Giesbers, Marcel Dijksterhuis, Jan Ingham, Colin J. Article/Letter to editor Frontiers in Microbiology 8 (2017) JUL ISSN: 1664-302X Physically triggered morphology changes in a novel Acremonium isolate cultivated in precisely engineered microfabricated environments 2017 Fungi are strongly affected by their physical environment. Microfabrication offers the possibility of creating new culture environments and ecosystems with defined characteristics. Here, we report the isolation of a novel member of the fungal genus Acremonium using a microengineered cultivation chip. This isolate was unusual in that it organizes into macroscopic structures when initially cultivated within microwells with a porous aluminum oxide (PAO) base. These "templated mycelial bundles" (TMB) were formed from masses of parallel hyphae with side branching suppressed. TMB were highly hydrated, facilitating the passive movement of solutes along the bundle. By using a range of culture chips, it was deduced that the critical factors in triggering the TMB were growth in microwells from 50 to 300 μm in diameter with a PAO base. Cultivation experiments, using spores and pigments as tracking agents, indicate that bulk growth of the TMB occurs at the base. TMB morphology is highly coherent and is maintained after growing out of the microwells. TMB can explore their environment by developing unbundled lateral hyphae; TMB only followed if nutrients were available. Because of the ease of fabricating numerous microstructures, we suggest this is a productive approach for exploring morphology and growth in multicellular microorganisms and microbial communities. en application/pdf https://research.wur.nl/en/publications/physically-triggered-morphology-changes-in-a-novel-acremonium-iso 10.3389/fmicb.2017.01269 https://edepot.wur.nl/420224 Cultivation chips Fungi Growth on surfaces Mycelial organization Simulated environments https://creativecommons.org/licenses/by/4.0/ Wageningen University & Research |
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Cultivation chips Fungi Growth on surfaces Mycelial organization Simulated environments Cultivation chips Fungi Growth on surfaces Mycelial organization Simulated environments |
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Cultivation chips Fungi Growth on surfaces Mycelial organization Simulated environments Cultivation chips Fungi Growth on surfaces Mycelial organization Simulated environments Catón, Laura Yurkov, Andrey Giesbers, Marcel Dijksterhuis, Jan Ingham, Colin J. Physically triggered morphology changes in a novel Acremonium isolate cultivated in precisely engineered microfabricated environments |
| description |
Fungi are strongly affected by their physical environment. Microfabrication offers the possibility of creating new culture environments and ecosystems with defined characteristics. Here, we report the isolation of a novel member of the fungal genus Acremonium using a microengineered cultivation chip. This isolate was unusual in that it organizes into macroscopic structures when initially cultivated within microwells with a porous aluminum oxide (PAO) base. These "templated mycelial bundles" (TMB) were formed from masses of parallel hyphae with side branching suppressed. TMB were highly hydrated, facilitating the passive movement of solutes along the bundle. By using a range of culture chips, it was deduced that the critical factors in triggering the TMB were growth in microwells from 50 to 300 μm in diameter with a PAO base. Cultivation experiments, using spores and pigments as tracking agents, indicate that bulk growth of the TMB occurs at the base. TMB morphology is highly coherent and is maintained after growing out of the microwells. TMB can explore their environment by developing unbundled lateral hyphae; TMB only followed if nutrients were available. Because of the ease of fabricating numerous microstructures, we suggest this is a productive approach for exploring morphology and growth in multicellular microorganisms and microbial communities. |
| format |
Article/Letter to editor |
| topic_facet |
Cultivation chips Fungi Growth on surfaces Mycelial organization Simulated environments |
| author |
Catón, Laura Yurkov, Andrey Giesbers, Marcel Dijksterhuis, Jan Ingham, Colin J. |
| author_facet |
Catón, Laura Yurkov, Andrey Giesbers, Marcel Dijksterhuis, Jan Ingham, Colin J. |
| author_sort |
Catón, Laura |
| title |
Physically triggered morphology changes in a novel Acremonium isolate cultivated in precisely engineered microfabricated environments |
| title_short |
Physically triggered morphology changes in a novel Acremonium isolate cultivated in precisely engineered microfabricated environments |
| title_full |
Physically triggered morphology changes in a novel Acremonium isolate cultivated in precisely engineered microfabricated environments |
| title_fullStr |
Physically triggered morphology changes in a novel Acremonium isolate cultivated in precisely engineered microfabricated environments |
| title_full_unstemmed |
Physically triggered morphology changes in a novel Acremonium isolate cultivated in precisely engineered microfabricated environments |
| title_sort |
physically triggered morphology changes in a novel acremonium isolate cultivated in precisely engineered microfabricated environments |
| url |
https://research.wur.nl/en/publications/physically-triggered-morphology-changes-in-a-novel-acremonium-iso |
| work_keys_str_mv |
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| _version_ |
1822269880235196416 |