Active bacterial community structure along vertical redox gradients in Baltic Sea sediment

Edlund, Anna; Hårdeman, Fredrik; Jansson, Janet; Sjöling, Sara

doi:10.1111/j.1462-2920.2008.01624.x

Cited by 79 publications

(68 citation statements)

References 44 publications

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“…Under anoxic conditions, many cyanobacteria are able to gain energy from fermentation of storage carbohydrates accumulated during photoautotrophic growth, but fermentation of external organic substrates in free-living cyanobacteria is poorly documented (14). Viability and growth of cyanobacteria under dark anoxic conditions have also been observed in Baltic Sea sediment, based on 16S rRNA libraries and incorporation of bromodeoxyuridine into DNA (15). Recently, Kamp et al (16) reported that diatoms are able to perform dissimilatory nitrate reduction of intracellular stored nitrate under anoxic dark conditions, which may aid in their survival in anoxic sediments.…”

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confidence: 89%

Depth-Related Differences in Organic Substrate Utilization by Major Microbial Groups in Intertidal Marine Sediment

Miyatake

MacGregor

Boschker

2013

Appl Environ Microbiol

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Stable isotope probing of magnetic-bead-captured rRNA (Mag-SIP) indicated clear differences in in situ organic substrate utilization by major microbial groups between the more oxidized (0 to 2 cm) and sulfate-reducing (2 to 5 cm) horizons of marine intertidal sediment. We also showed that cyanobacteria and diatoms may survive by glucose utilization under dark anoxic conditions. T he microbial community in marine sediments is highly diverse and consists mainly of microorganisms related only distantly to described isolates, whose functions are therefore difficult to predict (1-3). A recent study indicated a higher functional redundancy in the oxidized top layer of marine sediments, where higher disturbance rates and higher availability of substrates may lead to the formation of a community of fast-growing generalists (4). In contrast, a consortium of microbes consisting of specialized fermenting and sulfate-reducing bacteria is thought to be involved in organic matter degradation under sulfate-reducing conditions (5). However, intermediate metabolites are generally at low concentrations due to their high turnover rates, making in situ identification of the microbial groups utilizing them difficult. We utilized a recently developed stable isotope-probing method based on magnetic bead capturing of specific 16S rRNA and subsequent sensitive 13 C analysis of the captured material (Mag-SIP) (6, 7) to show major differences in substrate utilization by predominant microbial groups between the oxidized top layer and sulfate-reducing deeper layer of an intertidal marine sediment.In this study, sediment cores (internal diameter, 5.2 cm) were collected at an intertidal flat in the for amino acids and 0.9 mol 13 C cm Ϫ3 for the other three substrates. These substrates represent both major constituents of the organic matter pool (carbohydrates and amino acids) and the main fermentation products (acetate and propionate) in marine sediments. Cores were incubated (24 h, 14°C) and sectioned in surface layers (0 to 2 cm) and deeper layers (2 to 5 cm), which corresponded to a clear color change of the sediment from brown-yellow to dark gray. A nested set of probes targeting approximately 80% of the rRNA sequences recovered from the two sediment layers was used with the Mag-SIP protocol (7). The testing of the probes for total bacterial rRNA (EUB338), Deltaproteobacteria rRNA (DELTA495a), and Desulfobacteraceae rRNA (Dbact653) was previously described by Miyatake et al. (7). Probe CYA361 was used to target cyanobacterium and chloroplast rRNA (20% formamide [8]). We designed a new specific probe and matching helper probes that target the 16S rRNA of most Beta-and Gammaproteobacteria (specific probe BG553 sequence, CGC CCA GTA ATT CCG ATT [60% formamide]; helper probe BG553_up_help sequence, AAC CGC CTR CGN RCG CTT TA; helper probe BG553_down_help sequence, AAC GCT YGC ACC CTM CTG ATT). In this study, the BG553 probe is basically Gammaproteobacteria specific, as we did not detect Betaproteobacteriarelated sequences in any of the clone ...

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confidence: 89%

Depth-Related Differences in Organic Substrate Utilization by Major Microbial Groups in Intertidal Marine Sediment

Miyatake

MacGregor

Boschker

2013

Appl Environ Microbiol

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“…The steep halocline in the Baltic Proper, together with considerable eutrophication, leads to extreme differences in environment, such that very different microbial processes may dominate above and below the halocline. A number of studies have provided insights on the taxonomic diversity of microbial communities both in the water column [9], [10], [11], [12], [13] and coastal sediment [14], [15] while the study of functional capacity has primarily focused on specific functions [16], [17], [18], [19], [20], [21], [22], [23], [24] and the study of total community function in the Baltic Proper is therefore still in its infancy.…”

Section: Introductionmentioning

confidence: 99%

A Metagenomics Transect into the Deepest Point of the Baltic Sea Reveals Clear Stratification of Microbial Functional Capacities

et al. 2013

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The Baltic Sea is characterized by hyposaline surface waters, hypoxic and anoxic deep waters and sediments. These conditions, which in turn lead to a steep oxygen gradient, are particularly evident at Landsort Deep in the Baltic Proper. Given these substantial differences in environmental parameters at Landsort Deep, we performed a metagenomic census spanning surface to sediment to establish whether the microbial communities at this site are as stratified as the physical environment. We report strong stratification across a depth transect for both functional capacity and taxonomic affiliation, with functional capacity corresponding most closely to key environmental parameters of oxygen, salinity and temperature. We report similarities in functional capacity between the hypoxic community and hadal zone communities, underscoring the substantial degree of eutrophication in the Baltic Proper. Reconstruction of the nitrogen cycle at Landsort deep shows potential for syntrophy between archaeal ammonium oxidizers and bacterial denitrification at anoxic depths, while anaerobic ammonium oxidation genes are absent, despite substantial ammonium levels below the chemocline. Our census also reveals enrichment in genetic prerequisites for a copiotrophic lifestyle and resistance mechanisms reflecting adaptation to prevalent eutrophic conditions and the accumulation of environmental pollutants resulting from ongoing anthropogenic pressures in the Baltic Sea.

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“…To determine microbial diversity between samples, terminal restriction fragment length polymorphism (t-RFLP) analysis of bacterial and archaeal rRNA genes was performed on samples from both India and NCM. Each DNA suspension was amplified using the general bacterial primers 27F-FAM and 926R (11) or general archaeal primers 21F-FAM and 958R (6) in a MasterCycler thermocycler (Eppendorf, Westbury, NY). Each 20-l PCR mixture contained 1.25 units of AmpliTaq Gold LD (ABI, Foster City, CA), 1ϫ PCR buffer, 4 mM MgCl 2 , 800 M each deoxynucleoside triphosphate, 0.5 M each primer, and 8 g of bovine serum albumin.…”

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confidence: 99%

Macroscopic Biofilms in Fracture-Dominated Sediment That Anaerobically Oxidize Methane

Briggs

Pohlman

Torres

et al. 2011

Appl Environ Microbiol

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Methane release from seafloor sediments is moderated, in part, by the anaerobic oxidation of methane (AOM) performed by consortia of archaea and bacteria. These consortia occur as isolated cells and aggregates within the sulfate-methane transition (SMT) of diffusion and seep-dominant environments. Here we report on a new SMT setting where the AOM consortium occurs as macroscopic pink to orange biofilms within subseafloor fractures. Biofilm samples recovered from the Indian and northeast Pacific Oceans had a cellular abundance of 10 7 to 10 8 cells cm ؊3 . This cell density is 2 to 3 orders of magnitude greater than that in the surrounding sediments. Sequencing of bacterial 16S rRNA genes indicated that the bacterial component is dominated by Deltaproteobacteria, candidate division WS3, and Chloroflexi, representing 46%, 15%, and 10% of clones, respectively. In addition, major archaeal taxa found in the biofilm were related to the ANME-1 clade, Thermoplasmatales, and Desulfurococcales, representing 73%, 11%, and 10% of archaeal clones, respectively. The sequences of all major taxa were similar to sequences previously reported from cold seep environments. PhyloChip microarray analysis detected all bacterial phyla identified by the clone library plus an additional 44 phyla. However, sequencing detected more archaea than the PhyloChip within the phyla of Methanosarcinales and Desulfurococcales. The stable carbon isotope composition of the biofilm from the SMT (؊35 to ؊43‰) suggests that the production of the biofilm is associated with AOM. These biofilms are a novel, but apparently widespread, aggregation of cells represented by the ANME-1 clade that occur in methane-rich marine sediments.

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Active bacterial community structure along vertical redox gradients in Baltic Sea sediment

Cited by 79 publications

References 44 publications

Depth-Related Differences in Organic Substrate Utilization by Major Microbial Groups in Intertidal Marine Sediment

Depth-Related Differences in Organic Substrate Utilization by Major Microbial Groups in Intertidal Marine Sediment

A Metagenomics Transect into the Deepest Point of the Baltic Sea Reveals Clear Stratification of Microbial Functional Capacities

Macroscopic Biofilms in Fracture-Dominated Sediment That Anaerobically Oxidize Methane

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