Dynamics of dissolved methane and methane oxidation in dimictic Lake Nojiri during winter

Utsumi, Motoo; Nojiri, Yukihiro; Nakamura, Takeshi; Takeshi, Nozawa; Otsuki, Akira; Takamura, Noriko; Watanabe, Makoto M.; Seki, Humitake

doi:10.4319/lo.1998.43.1.0010

Cited by 95 publications

(100 citation statements)

References 20 publications

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“…Some other studies have also reported methane oxidation in lake water or sediments in the absence of O 2 , or at least at very low concentrations (1,35,42,54,62). Anaerobic oxidation of methane coupled to reduction of sulfate is well-known from various marine sediments (6,19,55) and saline lakes (29,31).…”

Section: Total Bacterial Abundancementioning

confidence: 99%

“…Aerobic methane-oxidizing bacteria (MOB) in the water columns of lakes consume a significant part of the methane produced in the sediment or in anaerobic layers of water (46,54). Besides metabolizing methane that would otherwise be emitted to the atmosphere, they represent a route for reentry of carbon back into the food-webs (2,26,30,46).…”

mentioning

confidence: 99%

“…It can proceed both under aerobic and anaerobic conditions, but the latter seems to be extensive primarily in waters with high ionic strength, e.g., saline lakes and marine systems (29,31,55). Many strains capable of aerobic methane oxidation have been isolated and characterized, and phylogenetically all belong to either the ␥-proteobacteria (commonly referred to as "type I" methanotrophs) or the ␣-proteobacteria ("type II" methanotrophs) (10,12,24).Aerobic methane-oxidizing bacteria (MOB) in the water columns of lakes consume a significant part of the methane produced in the sediment or in anaerobic layers of water (46,54). Besides metabolizing methane that would otherwise be emitted to the atmosphere, they represent a route for reentry of carbon back into the food-webs (2,26,30,46).…”

mentioning

confidence: 99%

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Abundance, Activity, and Community Structure of Pelagic Methane-Oxidizing Bacteria in Temperate Lakes

Sundh

Bastviken

Tranvik

2005

Appl Environ Microbiol

120

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The abundance and activity of methane-oxidizing bacteria (MOB) in the water column were investigated in three lakes with different contents of nutrients and humic substances. The abundance of MOB was determined by analysis of group-specific phospholipid fatty acids from type I and type II MOB, and in situ activity was measured with a 14 CH 4 transformation method. The fatty acid analyses indicated that type I MOB most similar to species of Methylomonas, Methylomicrobium, and Methylosarcina made a substantial contribution (up to 41%) to the total bacterial biomass, whereas fatty acids from type II MOB generally had very low concentrations. The MOB biomass and oxidation activity were positively correlated and were highest in the hypo-and metalimnion during summer stratification, whereas under ice during winter, maxima occurred close to the sediments. The methanotroph biomass-specific oxidation rate (V) ranged from 0.001 to 2.77 mg CH 4 -C mg ؊1 C day ؊1 and was positively correlated with methane concentration, suggesting that methane supply largely determined the activity and biomass distribution of MOB. Our results demonstrate that type I MOB often are a large component of pelagic bacterial communities in temperate lakes. They represent a potentially important pathway for reentry of carbon and energy into pelagic food webs that would otherwise be lost as evasion of CH 4 .Microbiological oxidation of methane takes place in many kinds of aquatic systems and soils (28,32,33,58) and plays an important role in the global budget of this greenhouse gas (15,43). It can proceed both under aerobic and anaerobic conditions, but the latter seems to be extensive primarily in waters with high ionic strength, e.g., saline lakes and marine systems (29,31,55). Many strains capable of aerobic methane oxidation have been isolated and characterized, and phylogenetically all belong to either the ␥-proteobacteria (commonly referred to as "type I" methanotrophs) or the ␣-proteobacteria ("type II" methanotrophs) (10,12,24).Aerobic methane-oxidizing bacteria (MOB) in the water columns of lakes consume a significant part of the methane produced in the sediment or in anaerobic layers of water (46,54). Besides metabolizing methane that would otherwise be emitted to the atmosphere, they represent a route for reentry of carbon back into the food-webs (2,26,30,46). In spite of this, direct studies of MOB populations in the pelagic systems of lakes are rare and, with the exception of a small oxbow lake (45) and a tropical hydropower reservoir (20, 21), very little is known about the abundance and population structure of pelagic methanotrophs in lakes.The aerobic methanotrophic bacteria contain some phospholipid fatty acids (PLFAs) that seem to be unique for this group of organisms (16:18c in type I MOB and 18:18c in type II MOB (10, 40). Analysis of these PLFAs has been shown to be a very sensitive tool for the direct study of populations of type I and type II MOB in samples from several different kinds of ecosystems (7,9,16,39,51).In the prese...

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Section: Total Bacterial Abundancementioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Abundance, Activity, and Community Structure of Pelagic Methane-Oxidizing Bacteria in Temperate Lakes

Sundh

Bastviken

Tranvik

2005

Appl Environ Microbiol

120

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“…For example, lakes emit roughly 8-48 Tg CH 4 year −1 , which is 6-16% of natural methane emissions and exceeds methane emissions from the ocean (Bastviken et al, 2004(Bastviken et al, , 2011Kirschke et al, 2013). In freshwater environments it has been estimated that anaerobic carbon mineralization contributes to 20-60% of total carbon mineralization rates (Boon and Mitchell, 1995;Hamilton et al, 1995;Utsumi et al, 1998), with methanogenesis making up 30-80% of this anaerobic activity (Kuivila et al, 1988;Bédard and Knowles, 1991). As such, it has been estimated that 20-59% of the OM delivered to sediments via suspended particles is converted to methane (Wetzel, 2001 and references therein).…”

Section: Methane Cycling In Inland Watersmentioning

confidence: 99%

Where Carbon Goes When Water Flows: Carbon Cycling across the Aquatic Continuum

et al. 2017

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The purpose of this review is to highlight progress in unraveling carbon cycling dynamics across the continuum of landscapes, inland waters, coastal oceans, and the atmosphere. Earth systems are intimately interconnected, yet most biogeochemical studies focus on specific components in isolation. The movement of water drives the carbon cycle, and, as such, inland waters provide a critical intersection between terrestrial and marine biospheres. Inland, estuarine, and coastal waters are well studied in regions near centers of human population in the Northern hemisphere. However, many of the world's large river systems and their marine receiving waters remain poorly characterized, particularly in the tropics, which contribute to a disproportionately large fraction of the transformation of terrestrial organic matter to carbon dioxide, and the Arctic, where positive feedback mechanisms are likely to amplify global climate change. There are large gaps in current coverage of environmental observations along the aquatic continuum. For example, tidally-influenced reaches of major rivers and near-shore coastal regions around river plumes are often left out of carbon budgets due to a combination of methodological constraints and poor data coverage. We suggest that closing these gaps could potentially alter global estimates of CO 2 outgassing from surface waters to the atmosphere by several-fold. Finally, in order to identify and constrain/embrace uncertainties in global carbon budget estimations it is important that we further adopt statistical and modeling approaches that have become well-established in the fields of oceanography and paleoclimatology, for example.

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“…In fact, for stratified lakes, methanotrophs can consume up to 90% of the dissolved CH 4 (Utsumi et al, 1998;Kankaala et al, 2006). However, in well-mixed estuaries, the activity of methanotrophs has been shown to be significantly less, allowing for the possible escape of CH 4 to the atmospshere (Abril et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

Mangrove Methane Biogeochemistry in the Indian Sundarbans: A Proposed Budget

2017

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Biogeochemical cycling of CH 4 was investigated at Lothian Island, one of the relatively pristine islands of Indian Sundarbans and its adjacent Saptamukhi estuary, during June 2010 to December 2012. Intertidal mangrove sediments were highly anoxic and rich in organic carbon. Mean rates of methanogenesis were 3,547 and 48.88 µmol m −3 wet sediment d −1 , for intertidal (up to 25 cm depth) and sub-tidal sediments (first 5 cm depth), respectively. CH 4 in pore-water was 53.4 times more supersaturated than in adjacent estuarine waters. This resulted in significant CH 4 efflux from sediments to estuarine waters-via advective and diffusive transport. About 8.2% of the total CH 4 produced in intertidal mangrove sediments was transported to the adjacent estuary through advective flux, which was 20 times higher than diffusive CH 4 flux. Mean CH 4 concentrations in estuarine surface and sub-surface waters were 69.9 and 56.1 nM, respectively, with a dissolved CH 4 oxidation rate in estuarine surface waters of 20.5 nmol L −1 d −1 . An estimated 0.09 Gg year −1 of CH 4 is released from estuaries of Sundarbans to the regional atmosphere. The mean CH 4 mixing ratio over the forest atmosphere was 2 ppmv. On annual basis, only 2.75% of total supplied CH 4 to the forest atmosphere was transported to the upper atmosphere via biosphere-atmosphere exchange. Mean CH 4 photo-oxidation rate over the forest atmosphere was 3.25 × 10 −9 mg cm −3 d −1 . Using new and previously published data we present for the first time, a CH 4 budget for Sundarbans mangrove ecosystem which in part, revealed the existence of anaerobic CH 4 oxidation in the mangrove sediment column.

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Dynamics of dissolved methane and methane oxidation in dimictic Lake Nojiri during winter

Cited by 95 publications

References 20 publications

Abundance, Activity, and Community Structure of Pelagic Methane-Oxidizing Bacteria in Temperate Lakes

Abundance, Activity, and Community Structure of Pelagic Methane-Oxidizing Bacteria in Temperate Lakes

Where Carbon Goes When Water Flows: Carbon Cycling across the Aquatic Continuum

Mangrove Methane Biogeochemistry in the Indian Sundarbans: A Proposed Budget

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