Anaerobic oxidation of methane at different temperature regimes in Guaymas Basin hydrothermal sediments

Biddle, Jennifer F.; Cardman, Z.; Mendlovitz, Howard P.; Albert, Daniel B.; Lloyd, Karen G.; Boetius, Antje; Teske, Andreas

doi:10.1038/ismej.2011.164

Cited by 142 publications

(188 citation statements)

References 43 publications

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“…This suggests that seafloor inputs of hydrocarbons have had a major and geographically widespread impact on the types and activities of microorganisms in the deep Gulf of California, leading to microbial communities with an enormous capacity for consumption of seafloor-derived methane. These results are consistent with prevalent diffusive seepage of methane from sediments, potentially including low-temperature surface sediments away from active hydrothermal venting (Lizarralde et al, 2011;Biddle et al, 2012). Interestingly, we recovered abundant transcript sequences encoding methane monooxygenases that were 100% identical to methanotrophs recently reported from the Deepwater Horizon oil spill (Kessler et al, 2011).…”

Section: Discussionsupporting

confidence: 88%

The metatranscriptome of a deep-sea hydrothermal plume is dominated by water column methanotrophs and lithotrophs

et al. 2012

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Microorganisms mediate geochemical processes in deep-sea hydrothermal vent plumes, which are a conduit for transfer of elements and energy from the subsurface to the oceans. Despite this important microbial influence on marine geochemistry, the ecology and activity of microbial communities in hydrothermal plumes is largely unexplored. Here, we use a coordinated metagenomic and metatranscriptomic approach to compare microbial communities in Guaymas Basin hydrothermal plumes to background waters above the plume and in the adjacent Carmen Basin. Despite marked increases in plume total RNA concentrations (3-4 times) and microbially mediated manganese oxidation rates (15-125 times), plume and background metatranscriptomes were dominated by the same groups of methanotrophs and chemolithoautotrophs. Abundant community members of Guaymas Basin seafloor environments (hydrothermal sediments and chimneys) were not prevalent in the plume metatranscriptome. De novo metagenomic assembly was used to reconstruct genomes of abundant populations, including Marine Group I archaea, Methylococcaceae, SAR324 Deltaproteobacteria and SUP05 Gammaproteobacteria. Mapping transcripts to these genomes revealed abundant expression of genes involved in the chemolithotrophic oxidation of ammonia (amo), methane (pmo) and sulfur (sox). Whereas amo and pmo gene transcripts were abundant in both plume and background, transcripts of sox genes for sulfur oxidation from SUP05 groups displayed a 10-20-fold increase in plumes. We conclude that the biogeochemistry of Guaymas Basin hydrothermal plumes is mediated by microorganisms that are derived from seawater rather than from seafloor hydrothermal environments such as chimneys or sediments, and that hydrothermal inputs serve as important electron donors for primary production in the deep Gulf of California.

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Section: Discussionsupporting

confidence: 88%

The metatranscriptome of a deep-sea hydrothermal plume is dominated by water column methanotrophs and lithotrophs

et al. 2012

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“…6). Only relatively low SR and AOM rates were measured at the vents, as compared to other methane-rich hydrothermal vents and seeps that are not impacted by CO 2 leakage (Biddle et al, 2011;Felden et al, 2010).…”

Section: Discussionmentioning

confidence: 81%

“…Microsensors for O 2 , H 2 S, and pH were made and used as described previously (de Beer et al, 1997;Jeroschewski et al, 1996;Revsbech, 1989). The tip diameters were approximately 20 µm, the response time (t 90 ) less than 3 s. A temperature sensor was used (Pt100, UST Umweltsensortechnik GmbH, Thüringen, Germany), with a length of 18 cm, a shaft and tip diameter of 3 mm and length of sensing element of 1 cm and a response time of ∼ 5 s. Microsensors for redox potential (ORP) were made from Pt wire of 50 µm diameter, fused in a glass capillary, leaving a length of 100 µm Pt exposed as sensing surface.…”

Section: Microprofilingmentioning

confidence: 99%

Saturated CO<sub>2</sub> inhibits microbial processes in CO<sub>2</sub>-vented deep-sea sediments

et al. 2013

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Abstract. This study focused on biogeochemical processes and microbial activity in sediments of a natural deep-sea CO2 seepage area (Yonaguni Knoll IV hydrothermal system, Japan). The aim was to assess the influence of the geochemical conditions occurring in highly acidic and CO2 saturated sediments on sulfate reduction (SR) and anaerobic methane oxidation (AOM). Porewater chemistry was investigated from retrieved sediment cores and in situ by microsensor profiling. The sites sampled around a sediment-hosted hydrothermal CO2 vent were very heterogeneous in porewater chemistry, indicating a complex leakage pattern. Near the vents, droplets of liquid CO2 were observed emanating from the sediments, and the pH reached approximately 4.5 in a sediment depth > 6 cm, as determined in situ by microsensors. Methane and sulfate co-occurred in most sediment samples from the vicinity of the vents down to a depth of 3 m. However, SR and AOM were restricted to the upper 7–15 cm below seafloor, although neither temperature, low pH, nor the availability of methane and sulfate could be limiting microbial activity. We argue that the extremely high subsurface concentrations of dissolved CO2 (1000–1700 mM), which disrupt the cellular pH homeostasis, and lead to end-product inhibition. This limits life to the surface sediment horizons above the liquid CO2 phase, where less extreme conditions prevail. Our results may have to be taken into consideration in assessing the consequences of deep-sea CO2 sequestration on benthic element cycling and on the local ecosystem state.

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“…Molecular ecological studies have indicated that the ANME-1 populations occur in deeper, more reductive and more sulfate-depleted habitats than the ANME-2 populations (Knittel et al, 2005;Krüger et al, 2008;Nunoura et al, 2008;Rossel et al, 2011;Yanagawa et al, 2011). Furthermore, the potentially thermophilic ANME-1 group has been recognized as a key component in certain hydrothermal ecosystems, such as Guaymas Basin and Juan de Fuca Ridge (Biddle et al, 2012;Lever et al, 2013;Merkel et al, 2013). This mcrA group of thermophilic ANME-1 is defined as Hydrothermal ANME-1 Cluster II (Lever et al, 2013) (alternatively classified as mcrA-Guaymas (Biddle et al, 2012) or ANME-1GBa (Merkel et al, 2013)).…”

Section: Microbial Functions Of Methanogenesis and Aommentioning

confidence: 99%

“…Furthermore, the potentially thermophilic ANME-1 group has been recognized as a key component in certain hydrothermal ecosystems, such as Guaymas Basin and Juan de Fuca Ridge (Biddle et al, 2012;Lever et al, 2013;Merkel et al, 2013). This mcrA group of thermophilic ANME-1 is defined as Hydrothermal ANME-1 Cluster II (Lever et al, 2013) (alternatively classified as mcrA-Guaymas (Biddle et al, 2012) or ANME-1GBa (Merkel et al, 2013)). The optimal growth temperatures of the thermophilic ANME-1 in the Guaymas site have been estimated to be above 70°C (Merkel et al, 2013).…”

Section: Microbial Functions Of Methanogenesis and Aommentioning

confidence: 99%

Defining boundaries for the distribution of microbial communities beneath the sediment-buried, hydrothermally active seafloor

et al. 2016

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Subseafloor microbes beneath active hydrothermal vents are thought to live near the upper temperature limit for life on Earth. We drilled and cored the Iheya North hydrothermal field in the MidOkinawa Trough, and examined the phylogenetic compositions and the products of metabolic functions of sub-vent microbial communities. We detected microbial cells, metabolic activities and molecular signatures only in the shallow sediments down to 15.8 m below the seafloor at a moderately distant drilling site from the active hydrothermal vents (450 m). At the drilling site, the profiles of methane and sulfate concentrations and the δ 13 C and δD isotopic compositions of methane suggested the laterally flowing hydrothermal fluids and the in situ microbial anaerobic methane oxidation. In situ measurements during the drilling constrain the current bottom temperature of the microbially habitable zone to~45°C. However, in the past, higher temperatures of 106-198°C were possible at the depth, as estimated from geochemical thermometry on hydrothermally altered clay minerals. The 16S rRNA gene phylotypes found in the deepest habitable zone are related to those of thermophiles, although sequences typical of known hyperthermophilic microbes were absent from the entire core. Overall our results shed new light on the distribution and composition of the boundary microbial community close to the high-temperature limit for habitability in the subseafloor environment of a hydrothermal field.

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Anaerobic oxidation of methane at different temperature regimes in Guaymas Basin hydrothermal sediments

Cited by 142 publications

References 43 publications

The metatranscriptome of a deep-sea hydrothermal plume is dominated by water column methanotrophs and lithotrophs

The metatranscriptome of a deep-sea hydrothermal plume is dominated by water column methanotrophs and lithotrophs

Saturated CO<sub>2</sub> inhibits microbial processes in CO<sub>2</sub>-vented deep-sea sediments

Defining boundaries for the distribution of microbial communities beneath the sediment-buried, hydrothermally active seafloor

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Anaerobic oxidation of methane at different temperature regimes in Guaymas Basin hydrothermal sediments

Cited by 142 publications

References 43 publications

The metatranscriptome of a deep-sea hydrothermal plume is dominated by water column methanotrophs and lithotrophs

The metatranscriptome of a deep-sea hydrothermal plume is dominated by water column methanotrophs and lithotrophs

Saturated CO&lt;sub&gt;2&lt;/sub&gt; inhibits microbial processes in CO&lt;sub&gt;2&lt;/sub&gt;-vented deep-sea sediments

Defining boundaries for the distribution of microbial communities beneath the sediment-buried, hydrothermally active seafloor

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Saturated CO<sub>2</sub> inhibits microbial processes in CO<sub>2</sub>-vented deep-sea sediments