Prokaryotic cells of the deep sub-seafloor biosphere identified as living bacteria

Schippers, Axel; Neretin, Lev N.; Kallmeyer, Jens; Ferdelman, Timothy G.; Cragg, Barry A.; Parkes, Ronald John; Jørgensen, Bo Barker

doi:10.1038/nature03302

Cited by 411 publications

(396 citation statements)

References 27 publications

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“…Microbial production was estimated with shipboard incubations of water samples with 3 H-leucine, and the offshore gradients in cell concentration of major taxonomic groups were determined by epifluorescence microscopy. Our approach included the application of a recently described molecular probe technique, the catalyzed reporter deposition for fluorescence in situ hybridization assay (CARD-FISH) (Pernthaler et al 2002, Schippers et al 2005. This method gives a much brighter detection of cells than the regular FISH approach, with values comparable to the application of polynucleotide probes (Pernthaler et al 2002).…”

Section: Resale or Republication Not Permitted Without Written Consenmentioning

confidence: 99%

Prokaryotic community structure and heterotrophic production in a river-influenced coastal arctic ecosystem

Garneau

Vincent²,

Alonso‐Sáez³

et al. 2006

Aquat. Microb. Ecol.

131

105

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Spatial patterns in prokaryotic biodiversity and production were assessed in the Mackenzie shelf region of the Beaufort Sea during open-water conditions. The sampling transect extended 350 km northwards, from upstream freshwater sites in the Mackenzie River to coastal and offshore sites, towards the edge of the perennial arctic ice pack. The analyses revealed strong gradients in community structure and prokaryotic cell concentrations, both of which correlated with salinity. Picocyanobacterial abundance was low (10 2 to 10 3 cells ml -1 ), particularly at the offshore stations that were least influenced by the river plume. Analysis by catalyzed reporter deposition for fluorescence in situ hybridization (CARD-FISH) showed that the dominant heterotrophic cell types were β-Proteobacteria at river sites, shifting to dominance by α-Proteobacteria offshore. Cells in the Cytophaga-Flavobacter-Bacteroides and γ-Proteobacteria groups each contributed < 5% of total counts in the river, but >10% of counts in the marine samples. Archaea were detected among the surface-water microbiota, contributing on average 1.3% of the total DAPI counts in marine samples, but 6.0% in turbid coastal and riverine waters. 3 H-leucine uptake rates were significantly higher at 2 stations influenced by the river (1.5 pmol l -1 h -1 ) than at other marine stations or in the river itself (≤0.5 pmol -1 h -1 ). Size-fractionation experiments at 2 coastal sites showed that > 65% of heterotrophic production was associated with particles > 3 µm. These results indicate the importance of particleattached prokaryotes, and imply a broad functional diversity of heterotrophic microbes that likely facilitates breakdown of the heterogeneous dissolved and particulate terrestrial materials discharged into arctic seas. KEY WORDS:Prokaryote diversity · Archaea · Proteobacteria · Cytophaga-FlavobacterBacteroides · Arctic Ocean · Mackenzie River estuary · Picocyanobacteria · CARD-FISH Resale or republication not permitted without written consent of the publisherAquat Microb Ecol 42: [27][28][29][30][31][32][33][34][35][36][37][38][39][40] 2006 ments (Payette et al. 2004) may mobilize the large stocks of organic carbon contained within their soils and cause increased transfer of these materials to arctic rivers and ultimately to the ocean. Heterotrophic microbiota are likely to play a major role in the response of coastal arctic ecosystems to ongoing change, but prokaryotic diversity and production in these cold ocean environments have been little explored (Amon 2004).In the western Canadian Arctic, the Mackenzie River discharges large quantities of freshwater, solutes and sediments into a vast shelf region of the Beaufort Sea that extends >100 km offshore and encompasses a total area of 63 600 km 2 (Carmack et al. 2004). The annual discharge of the Mackenzie River (330 km 3 yr -1 ; Macdonald et al. 1998) is the 4th highest in the Arctic Basin after the Siberian rivers Yenisei, Lena and Ob, with concomitantly large inputs of freshwater biota, terrestria...

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Section: Resale or Republication Not Permitted Without Written Consenmentioning

confidence: 99%

Prokaryotic community structure and heterotrophic production in a river-influenced coastal arctic ecosystem

Garneau

Vincent²,

Alonso‐Sáez³

et al. 2006

Aquat. Microb. Ecol.

131

105

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“…We hypothesize that the strong oxygen sensitivity of ANME organisms (Treude et al, 2005b) may not allow prolonged water-column survival time even if their exposure to oxygen during the runtime of the experiment and recovery of the water samples was relatively short with a maximum of 120 min. Consequently, the applied CARD-FISH technique would have failed to detect dead ANME-2 cells if present, because the targeted RNA quickly degenerates after cell death (Schippers et al, 2005).…”

mentioning

confidence: 99%

Bubble Transport Mechanism: Indications for a gas bubble-mediated inoculation of benthic methanotrophs into the water column

Schmale

Leifer

Deimling

et al. 2015

Continental Shelf Research

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“…Published assays for the quantification of the 16S rRNA gene copy numbers of Archaea (Takai and Horikoshi, 2000) and Bacteria (Nadkarni et al, 2002) were applied. 16S rRNA gene copy numbers were converted to cell numbers using conversion factors of 1.5 for Archaea and 4.1 for Bacteria, as previously done (Schippers et al, 2005).…”

Section: Methodsmentioning

confidence: 99%

“…Specific archaeal communities for sediments with different trophic states could be detected (Durbin and Teske, 2012). An open question is if Bacteria or Archaea dominate in oligotrophic sediments as previously discussed for eutrophic sediments based on quantitative polymerase chain reaction (qPCR) analysis (Schippers et al, 2005(Schippers et al, , 2012. Similar to oligotrophic Pacific sediments, oligotrophic (total organic carbon = ~0.15% ± 0.07%) and oxic sediments from the North Pond area in the 7 m.y.…”

Section: Introductionmentioning

confidence: 99%

“…It is mainly controlled by the content of organic carbon in the sediment as the microbial substrate (Parkes et al, 1994;D'Hondt et al, 2004;Schippers et al, 2005Schippers et al, , 2012Edwards et al, 2012;Kallmeyer et al, 2012;Lomstein et al, 2012;Hoehler and Jørgensen, 2013). Organic-lean, oligotrophic, and oxic sediments of the Pacific host oxygen-respiring prokaryotes (Røy et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

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Data report: total cell counts and qPCR abundance of Archaea and Bacteria in shallow subsurface marine sediments of North Pond: gravity cores collected during site survey cruise prior to IODP Expedition 336

Breuker¹

2013

Proceedings of the IODP

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Prokaryotic cells of the deep sub-seafloor biosphere identified as living bacteria

Cited by 411 publications

References 27 publications

Prokaryotic community structure and heterotrophic production in a river-influenced coastal arctic ecosystem

Prokaryotic community structure and heterotrophic production in a river-influenced coastal arctic ecosystem

Bubble Transport Mechanism: Indications for a gas bubble-mediated inoculation of benthic methanotrophs into the water column

Data report: total cell counts and qPCR abundance of Archaea and Bacteria in shallow subsurface marine sediments of North Pond: gravity cores collected during site survey cruise prior to IODP Expedition 336

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