Carbon Amendments Alter Microbial Community Structure and Net Mercury Methylation Potential in Sediments

Christensen, Geoff A.; Somenahally, Anil; Moberly, James G.; Miller, Christine; King, Andrew J.; Gilmour, Cynthia C.; Brown, Steven D.; Podar, Mircea; Brandt, Craig C.; Brooks, Scott C.; Palumbo, Anthony V.; Wall, Judy D.; Elias, Dwayne A.

doi:10.1128/aem.01049-17

Cited by 40 publications

(44 citation statements)

References 66 publications

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“…Nutrient cycling and cometabolic Hg transformations stand to be closely linked in Hg methylation hotspots such as periphytic microbial mats (Olsen, Brandt, & Brooks, ), aquatic sediments (Correia & Guimarães, ; Fleming, Mack, Green, & Nelson, ) and waterlogged soils (Eklof et al, ). While our study makes a case for sulphur cycling as a coupling point for competing cometabolic Hg transformations, other nutrients such as iron (Bravo et al, ; Fleming et al, ; Sugio et al, ; Wiatrowski et al, ) and organic carbon (Christensen et al, ; Grégoire et al, ; Grégoire & Poulain, ) that are known to control Hg methylation and reduction have the potential to fulfil a similar role. Curiously, the coupling between other macronutrients under strong microbial control, such as nitrogen, and Hg cycling remains unexplored despite the importance of nitrogen cycling in aquatic and terrestrial ecosystems.…”

Section: Resultsmentioning

confidence: 91%

Reduced sulphur sources favour Hg^II reduction during anoxygenic photosynthesis by Heliobacteria

et al. 2019

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The consumption of rice has become a global food safety issue because rice paddies support the production of high levels of the potent neurotoxin, methylmercury. The production of methylmercury is carried out by chemotrophic anaerobes that rely on a diversity of terminal electron acceptors, namely sulphate. Sulphur can be a limiting nutrient in rice paddies, and sulphate amendments are often used to stimulate crop production, which can increase methylmercury production. Mercury (Hg) redox cycling can affect Hg methylation by controlling the delivery of inorganic Hg substrates to methylators in anoxic habitats. Whereas sulphur is recognized as a key substrate controlling methylmercury production, the controls sulphur exerts on other microbe‐mediated Hg transformations remain poorly understood. To explore the potential coupling between sulphur assimilation and anaerobic HgII reduction to Hg0, we studied Heliobacillus mobilis, a mesophilic anoxygenic phototroph representative from the Heliobacteriacea family originally isolated from a rice paddy. Here, we tested whether the redox state of the sulphur sources available to H. mobilis would affect its ability to reduce HgII. By comparing Hg0 production over a redox gradient of sulphur sources, we demonstrate that phototrophic HgII reduction is favoured in the presence of reduced sulphur sources such as thiosulphate and cysteine. We also show that cysteine exerts dynamic control on Hg cycling by affecting not only Hg's bioavailability but also its abiotic photoreduction under low light conditions. Specifically, in the absence of cells we show that organic matter (as yeast extract) and cysteine are both required for photoreduction to occur. This study offers insights into how one of the most primitive forms of photosynthesis affects Hg redox transformations and frames Heliobacteria as key players in Hg cycling within paddy soils, forming a basis for management strategies to mitigate Hg accumulation in rice.

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Section: Resultsmentioning

confidence: 91%

Reduced sulphur sources favour Hg^II reduction during anoxygenic photosynthesis by Heliobacteria

et al. 2019

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“…Based on a higher number of sequenced microbial genomes now available, Christensen et al () developed a broad range hgcAB primer pair that improved the coverage of prior developed primers by 10% (Bae et al ; Schaefer et al ), and several clade‐specific PCR primers to improve amplification of the various members of the Hg II ‐methylating community (Christensen et al ) (Table ). In sediments, these clade‐specific primers were useful to detect Hg II ‐methylating δ‐Proteobacteria and Archaea but failed to detect Hg II ‐methylating Firmicutes (Christensen et al ).…”

Section: Toward a Better Understanding Of Microbial Methylmercury Formentioning

confidence: 99%

“…Despite the differences in primer pairs used in the studies mentioned earlier (Table ), until now, data globally suggested that in hgcA + δ‐Proteobacteria communities are abundant in surface sediments, but in some sites hgcA + methanogens and other hgcA + uncultivated groups are prevalent (Christensen et al , ; Vishnivetskaya et al ; Bravo et al ; Jones et al ). Among δ‐Proteobacteria , syntrophs and Geobacter spp.…”

Section: Toward a Better Understanding Of Microbial Methylmercury Formentioning

confidence: 99%

“…Natural OM, besides its strong capacity to bind Hg II and influence Hg II speciation, controls microbial activity and Hg II methylation (Graham et al ; Hsu‐Kim et al ). The molecular composition of OM shows a central role in controlling Hg II methylation (Bravo et al ), notably phytoplankton derived OM and fresh humic matter were associated with both high bacterial activity and Hg II methylation rates in sediments (Graham et al ; Schartup et al ; Mazrui et al ; Bravo et al ; Christensen et al ; Herrero Ortega et al ). Also, an increase in nutrients, associated to an enhanced algae biomass production, increased MMHg formation in sediments (Bravo et al ; Herrero Ortega et al ).…”

Section: Physico‐chemistry Plays a Pivotal Role In Hgii Methylationmentioning

confidence: 99%

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Biotic formation of methylmercury: A bio–physico–chemical conundrum

Bravo

Cosio

2019

Limnology & Oceanography

100

102

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Mercury (Hg) is a natural and widespread trace metal, but is considered a priority pollutant, particularly its organic form methylmercury (MMHg), because of human's exposure to MMHg through fish consumption. Pioneering studies showed the methylation of divalent Hg (HgII) to MMHg to occur under oxygen‐limited conditions and to depend on the activity of anaerobic microorganisms. Recent studies identified the hgcAB gene cluster in microorganisms with the capacity to methylate HgII and unveiled a much wider range of species and environmental conditions producing MMHg than previously expected. Here, we review the recent knowledge and approaches used to understand HgII‐methylation, microbial biodiversity and activity involved in these processes, and we highlight the current limits for predicting MMHg concentrations in the environment. The available data unveil the fact that HgII methylation is a bio‐physico‐chemical conundrum in which the efficiency of biological HgII methylation appears to depend chiefly on HgII and nutrients availability, the abundance of electron acceptors such as sulfate or iron, the abundance and composition of organic matter as well as the activity and structure of the microbial community. An increased knowledge of the relationship between microbial community composition, physico‐chemical conditions, MMHg production, and demethylation is necessary to predict variability in MMHg concentrations across environments.

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“…Recently, clade-specific quantitative PCR (qPCR) assays were developed to quantify the abundance of hgcA gene of the main methylators [10]. Hence, hgcAB and hgcA distribution can be used to predict occurrence of potential Hg methylators in the environment [11]. Understanding hgcAB and hgcA distribution is essential for estimating MeHg production in the water column and biomagnification in food webs [12].…”

Section: Introductionmentioning

confidence: 99%

Mercury-methylating bacteria are associated with copepods: A proof-of-principle survey in the Baltic Sea

2020

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Methylmercury (MeHg) is a potent neurotoxin that biomagnifies in marine food webs. Inorganic mercury (Hg) methylation is conducted by heterotrophic bacteria inhabiting sediment or settling detritus, but endogenous methylation by the gut microbiome of animals in the lower food webs is another possible source. We examined the occurrence of the bacterial gene (hgcA), required for Hg methylation, in the guts of dominant zooplankters in the Northern Baltic Sea. A qPCR assay targeting the hgcA sequence in three main clades (Deltaproteobacteria, Firmicutes and Archaea) was used in the field-collected specimens of copepods (Acartia bifilosa, Eurytemora affinis, Pseudocalanus acuspes and Limnocalanus macrurus) and cladocerans (Bosmina coregoni maritima and Cercopagis pengoi). All copepods were found to carry hgcA genes in their gut microbiome, whereas no amplification was recorded in the cladocerans. In the copepods, hgcA genes belonging to only Deltaproteobacteria and Firmicutes were detected. These findings suggest a possibility that endogenous Hg methylation occurs in zooplankton and may contribute to seasonal, spatial and vertical MeHg variability in the water column and food webs. Additional molecular and metagenomics studies are needed to identify bacteria carrying hgcA genes and improve their quantification in microbiota.

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Carbon Amendments Alter Microbial Community Structure and Net Mercury Methylation Potential in Sediments

Cited by 40 publications

References 66 publications

Reduced sulphur sources favour Hg^II reduction during anoxygenic photosynthesis by Heliobacteria

Reduced sulphur sources favour Hg^II reduction during anoxygenic photosynthesis by Heliobacteria

Biotic formation of methylmercury: A bio–physico–chemical conundrum

Mercury-methylating bacteria are associated with copepods: A proof-of-principle survey in the Baltic Sea

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Carbon Amendments Alter Microbial Community Structure and Net Mercury Methylation Potential in Sediments

Cited by 40 publications

References 66 publications

Reduced sulphur sources favour HgII reduction during anoxygenic photosynthesis by Heliobacteria

Reduced sulphur sources favour HgII reduction during anoxygenic photosynthesis by Heliobacteria

Biotic formation of methylmercury: A bio–physico–chemical conundrum

Mercury-methylating bacteria are associated with copepods: A proof-of-principle survey in the Baltic Sea

Contact Info

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Reduced sulphur sources favour Hg^II reduction during anoxygenic photosynthesis by Heliobacteria

Reduced sulphur sources favour Hg^II reduction during anoxygenic photosynthesis by Heliobacteria