Methane-Derived Carbon as a Driver for Cyanobacterial Growth

Methane-Derived Carbon as a Driver for Cyanobacterial Growth

Methane, a potent greenhouse gas produced in freshwater ecosystems, can be used by methane-oxidizing bacteria (MOB) and can therefore subsidize the pelagic food web with energy and carbon. Consortia of MOB and photoautotrophs have been described in aquatic ecosystems and MOB can benefit from photoau...

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Published in:Frontiers in microbiology Vol. 13; p. 837198
Main Authors: Cerbin, Slawek, Pérez, Germán, Rybak, Michał, Wejnerowski, Łukasz, Konowalczyk, Adam, Helmsing, Nico, Naus-Wiezer, Suzanne, Meima-Franke, Marion, Pytlak, Łukasz, Raaijmakers, Ciska, Nowak, Witold, Bodelier, Paul L E
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 01-04-2022
Subjects:
co-culture
greenhouse gases
isotopes
lakes
methane
methane oxidation
Microbiology
greenhouse gases
isotopes
cyanobacteria
methane
lakes
co-culture
methane oxidation
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Summary:Methane, a potent greenhouse gas produced in freshwater ecosystems, can be used by methane-oxidizing bacteria (MOB) and can therefore subsidize the pelagic food web with energy and carbon. Consortia of MOB and photoautotrophs have been described in aquatic ecosystems and MOB can benefit from photoautotrophs which produce oxygen, thereby enhancing CH oxidation. Methane oxidation can account for accumulation of inorganic carbon (i.e., CO ) and the release of exometabolites that may both be important factors influencing the structure of phytoplankton communities. The consortium of MOB and phototroph has been mainly studied for methane-removing biotechnologies, but there is still little information on the role of these interactions in freshwater ecosystems especially in the context of cyanobacterial growth and bloom development. We hypothesized that MOB could be an alternative C source to support cyanobacterial growth in freshwater systems. We detected low δ C values in cyanobacterial blooms (the lowest detected value -59.97‰ for ) what could be the result of the use of methane-derived carbon by cyanobacteria and/or MOB attached to their cells. We further proved the presence of metabolically active MOB on cyanobacterial filaments using the fluorescein isothiocyanate (FITC) based activity assay. The PCR results also proved the presence of the gene in several non-axenic cultures of cyanobacteria. Finally, experiments comprising the co-culture of the cyanobacterium with the methanotroph proved that cyanobacterial growth was significantly improved in the presence of MOB, presumably through utilizing CO released by MOB. On the other hand, C-CH labeled incubations showed the uptake and assimilation of MOB-derived metabolites by the cyanobacterium. We also observed a higher growth of MOB in the presence of cyanobacteria under a higher irradiance regime, then when grown alone, underpinning the bidirectional influence with as of yet unknown environmental consequences.
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Edited by: Mark Alexander Lever, ETH Zürich, Switzerland
This article was submitted to Aquatic Microbiology, a section of the journal Frontiers in Microbiology
ORCID: Slawek Cerbin, orcid.org/0000-0002-2800-0390; Michał Rybak, orcid.ord/0000-0001-7957-184X; Łukasz Wejnerowski, orcid.org/0000-0002-2690-4302
Reviewed by: Svetlana N. Dedysh, Winogradsky Institute of Microbiology (RAS), Russia; Sigrid Van Grinsven, Swiss Federal Institute of Aquatic Science and Technology, Switzerland
ISSN:1664-302X
1664-302X
DOI:10.3389/fmicb.2022.837198