Aerobic methane production by planktonic microbes in lakes

Aerobic methane production by planktonic microbes in lakes

Methanogenesis in freshwater lakes has classically been considered to arise from anaerobic methanogens in oxygen-depleted sediments. However, the accumulation of supersaturated methane in fully oxygenated water columns is commonly observed in many lakes, and factors responsible for the formation of...

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Bibliographic Details
Published in:The Science of the total environment Vol. 696; p. 133916
Main Authors: Khatun, Santona, Iwata, Tomoya, Kojima, Hisaya, Fukui, Manabu, Aoki, Takuya, Mochizuki, Seito, Naito, Azusa, Kobayashi, Ai, Uzawa, Ryo
Format: Journal Article
Language:English
Published: Elsevier B.V 15-12-2019
Subjects:
Cyanobacteria
Freshwater lakes
Methane
Phosphonates
Subsurface methane maximum
Synechococcus
Methane
Freshwater lakes
Cyanobacteria
Phosphonates
Synechococcus
Subsurface methane maximum
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Summary:Methanogenesis in freshwater lakes has classically been considered to arise from anaerobic methanogens in oxygen-depleted sediments. However, the accumulation of supersaturated methane in fully oxygenated water columns is commonly observed in many lakes, and factors responsible for the formation of the subsurface methane maximum (SMM) remain largely unknown. The present study conducted in 14 Japanese freshwater lakes showed that the SMM formation during the summer stratification period is a common feature in large and deep oligotrophic lakes. The seasonal survey of a deep oligotrophic lake revealed that SMM formation may be uncoupled with the dissolution of atmospheric methane, as well as with the transport of methane from tributary rivers, littoral sediments, and hypolimnetic anoxic sources, suggesting the contribution of in situ methane production. In fact, batch-culture experiments confirmed that bacterioplankton present in lake subsurface waters produce methane aerobically through the decomposition of methylphosphonic acid. Moreover, the development of SMM was closely associated with the seasonal dynamics of planktonic cyanobacteria such as Synechococcus, which may carry the enzyme to catabolize organophosphonate compounds. Therefore, we suggest that the predominance of Synechococcus during the thermal stratification period plays a significant role in SMM formation, and likely the methane flux from lakes to the atmosphere. [Display omitted] •The study examined the subsurface CH4 maximum (SMM) formation in oxic lake waters.•The SMM found in deep lakes was associated with the dynamics of cyanobacteria.•Lake P depletion may cause cyanobacterial CH4 production by phosphonate metabolism.•Enhanced oligotrophy by mixing regime alteration could promote CH4 flux from lakes.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2019.133916