Long-distance electron transport occurs globally in marine sediments

Burdorf, Laurine D. W.; Tramper, A.; Seitaj, Dorina; Meire, Lorenz; Hidalgo‐Martinez, Silvia; Zetsche, Eva‐Maria; Boschker, Henricus T. S.; Meysman, Filip J. R.

doi:10.5194/bg-14-683-2017

Cited by 96 publications

(86 citation statements)

References 53 publications

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“…This discovery has changed our view on sediment biogeochemistry. Cable bacteria have been found globally in a variety of different benthic environments characterized by moderate to high sulfide concentrations (Burdorf et al ., ). Cable bacteria belonging to the family Desulfobulbaceae transport electrons in marine and freshwater sediments over distances as long as 10 mm and more (Pfeffer et al ., ) (Fig.…”

Section: Cable Bacteria and The Sulfur Cyclementioning

confidence: 97%

Phototrophic marine benthic microbiomes: the ecophysiology of these biological entities

Stal

Bolhuis

Cretoiu

2018

Environmental Microbiology

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Summary Phototrophic biofilms are multispecies, self‐sustaining and largely closed microbial ecosystems. They form macroscopic structures such as microbial mats and stromatolites. These sunlight‐driven consortia consist of a number of functional groups of microorganisms that recycle the elements internally. Particularly, the sulfur cycle is discussed in more detail as this is fundamental to marine benthic microbial communities and because recently exciting new insights have been obtained. The cycling of elements demands a tight tuning of the various metabolic processes and require cooperation between the different groups of microorganisms. This is likely achieved through cell‐to‐cell communication and a biological clock. Biofilms may be considered as a macroscopic biological entity with its own physiology. We review the various components of some marine phototrophic biofilms and discuss their roles in the system. The importance of extracellular polymeric substances (EPS) as the matrix for biofilm metabolism and as substrate for biofilm microorganisms is discussed. We particularly assess the importance of extracellular DNA, horizontal gene transfer and viruses for the generation of genetic diversity and innovation, and for rendering resilience to external forcing to these biological entities.

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Section: Cable Bacteria and The Sulfur Cyclementioning

confidence: 97%

Phototrophic marine benthic microbiomes: the ecophysiology of these biological entities

Stal

Bolhuis

Cretoiu

2018

Environmental Microbiology

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“…The high pore water concentrations of H 2 S and the absence of bioturbation are characteristic features of marine sediments exposed to anoxic bottom waters. Upon bottom water re‐oxygenation, such sediments appear to offer a particularly suitable habitat for cable bacteria (Burdorf et al ., ). For example, high densities and activity of cable bacteria are consistently found in Lake Grevelingen, a seasonally hypoxic coastal water body in the Netherlands, after the re‐appearance of O 2 in the bottom water in fall (Seitaj et al ., ).…”

Section: Introductionmentioning

confidence: 97%

“…Cable bacteria have now been reported from an increasing number of sites (Burdorf et al ., ). These observations are largely derived from indirect observations, such as ex situ sediment enrichments or from 16S rRNA sequence databases.…”

Section: Introductionmentioning

confidence: 99%

Transient bottom water oxygenation creates a niche for cable bacteria in long‐term anoxic sediments of the Eastern Gotland Basin

Marzocchi

Bonaglia

Velde

et al. 2018

Environmental Microbiology

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Cable bacteria have been reported in sediments from marine and freshwater locations, but the environmental factors that regulate their growth in natural settings are not well understood. Most prominently, the physiological limit of cable bacteria in terms of oxygen availability remains poorly constrained. In this study, we investigated the presence, activity and diversity of cable bacteria in relation to a natural gradient in bottom water oxygenation in a depth transect of the Eastern Gotland Basin (Baltic Sea). Cable bacteria were identified by FISH at the oxic and transiently oxic sites, but not at the permanently anoxic site. Three species of the candidate genus Electrothrix, i.e. marina, aarhusiensis and communis were found coexisting within one site. The highest filament density (33 m cm ) was associated with a 6.3 mm wide zone depleted in both oxygen and free sulphide, and the presence of an electric field resulting from the electrogenic sulphur oxidizing metabolism of cable bacteria. However, the measured filament densities and metabolic activities remained low overall, suggesting a limited impact of cable bacteria at the basin level. The observed bottom water oxygen levels (< 5 μM) are the lowest so far reported for cable bacteria, thus expanding their known environmental distribution.

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“…In addition to Beggiatoa , succession of other microbes that influence the biogeochemistry of the surrounding sediment may alter N cycling. The recently described cable bacteria have been found in a large number of locations worldwide (Burdorf et al ). These organisms form chains to bridge spatially separated electron donor (sulfide) and acceptor (oxygen or NO 3 − ) (Nielsen et al ; Pfeffer et al ; Marzocchi et al ) and thereby transfer electrons over centimeter distances in sediments.…”

Section: Discussion and Outlookmentioning

confidence: 99%

Application of the isotope pairing technique in sediments: Use, challenges, and new directions

Robertson

Bartoli

Brüchert

et al. 2019

Limnology & Ocean Methods

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Determining accurate rates of benthic nitrogen (N) removal and retention pathways from diverse environments is critical to our understanding of process distribution and constructing reliable N budgets and models. The whole‐core 15N isotope pairing technique (IPT) is one of the most widely used methods to determine rates of benthic nitrate‐reducing processes and has provided valuable information on processes and factors controlling N removal and retention in aquatic systems. While the whole core IPT has been employed in a range of environments, a number of methodological and environmental factors may lead to the generation of inaccurate data and are important to acknowledge for those applying the method. In this review, we summarize the current state of the whole core IPT and highlight some of the important steps and considerations when employing the technique. We discuss environmental parameters which can pose issues to the application of the IPT and may lead to experimental artifacts, several of which are of particular importance in environments heavily impacted by eutrophication. Finally, we highlight the advances in the use of the whole‐core IPT in combination with other methods, discuss new potential areas of consideration and encourage careful and considered use of the whole‐core IPT. With the recognition of potential issues and proper use, the whole‐core IPT will undoubtedly continue to develop, improve our understanding of benthic N cycling and allow more reliable budgets and predictions to be made.

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Long-distance electron transport occurs globally in marine sediments

Cited by 96 publications

References 53 publications

Phototrophic marine benthic microbiomes: the ecophysiology of these biological entities

Phototrophic marine benthic microbiomes: the ecophysiology of these biological entities

Transient bottom water oxygenation creates a niche for cable bacteria in long‐term anoxic sediments of the Eastern Gotland Basin

Application of the isotope pairing technique in sediments: Use, challenges, and new directions

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