Your search keyword '"Caitlin M. Gionfriddo"' showing total 25 results

1. Nutrient Exposure Alters Microbial Composition, Structure, and Mercury Methylating Activity in Periphyton in a Contaminated Watershed

Author

Alyssa A. Carrell, Grace E. Schwartz, Melissa A. Cregger, Caitlin M. Gionfriddo, Dwayne A. Elias, Regina L. Wilpiszeski, Dawn M. Klingeman, Ann M. Wymore, Katherine A. Muller, and Scott C. Brooks

Subjects

periphyton, mercury, microbiome, methylmercury, nutrient addition, Microbiology, QR1-502

Abstract

The conversion of mercury (Hg) to monomethylmercury (MMHg) is a critical area of concern in global Hg cycling. Periphyton biofilms may harbor significant amounts of MMHg but little is known about the Hg-methylating potential of the periphyton microbiome. Therefore, we used high-throughput amplicon sequencing of the 16S rRNA gene, ITS2 region, and Hg methylation gene pair (hgcAB) to characterize the archaea/bacteria, fungi, and Hg-methylating microorganisms in periphyton communities grown in a contaminated watershed in East Tennessee (United States). Furthermore, we examined how nutrient amendments (nitrate and/or phosphate) altered periphyton community structure and function. We found that bacterial/archaeal richness in experimental conditions decreased in summer and increased in autumn relative to control treatments, while fungal diversity generally increased in summer and decreased in autumn relative to control treatments. Interestingly, the Hg-methylating communities were dominated by Proteobacteria followed by Candidatus Atribacteria across both seasons. Surprisingly, Hg methylation potential correlated with numerous bacterial families that do not contain hgcAB, suggesting that the overall microbiome structure of periphyton communities influences rates of Hg transformation within these microbial mats. To further explore these complex community interactions, we performed a microbial network analysis and found that the nitrate-amended treatment resulted in the highest number of hub taxa that also corresponded with enhanced Hg methylation potential. This work provides insight into community interactions within the periphyton microbiome that may contribute to Hg cycling and will inform future research that will focus on establishing mixed microbial consortia to uncover mechanisms driving shifts in Hg cycling within periphyton habitats.

Published

2021

2. An Improved hgcAB Primer Set and Direct High-Throughput Sequencing Expand Hg-Methylator Diversity in Nature

Author

Caitlin M. Gionfriddo, Ann M. Wymore, Daniel S. Jones, Regina L. Wilpiszeski, Mackenzie M. Lynes, Geoff A. Christensen, Ally Soren, Cynthia C. Gilmour, Mircea Podar, and Dwayne A. Elias

Subjects

amplicon sequencing, hgcAB, primer development, mercury methylation, environmental microbiology, microbial diversity, Microbiology, QR1-502

Abstract

The gene pair hgcAB is essential for microbial mercury methylation. Our understanding of its abundance and diversity in nature is rapidly evolving. In this study we developed a new broad-range primer set for hgcAB, plus an expanded hgcAB reference library, and used these to characterize Hg-methylating communities from diverse environments. We applied this new Hg-methylator database to assign taxonomy to hgcA sequences from clone, amplicon, and metagenomic datasets. We evaluated potential biases introduced in primer design, sequence length, and classification, and suggest best practices for studying Hg-methylator diversity. Our study confirms the emerging picture of an expanded diversity of HgcAB-encoding microbes in many types of ecosystems, with abundant putative mercury methylators Nitrospirae and Chloroflexi in several new environments including salt marsh and peat soils. Other common microbes encoding HgcAB included Phycisphaerae, Aminicenantes, Spirochaetes, and Elusimicrobia. Combined with high-throughput amplicon specific sequencing, the new primer set also indentified novel hgcAB sequences similar to Lentisphaerae, Bacteroidetes, Atribacteria, and candidate phyla WOR-3 and KSB1 bacteria. Gene abundance data also corroborate the important role of two “classic” groups of methylators (Deltaproteobacteria and Methanomicrobia) in many environments, but generally show a scarcity of hgcAB+ Firmicutes. The new primer set was developed to specifically target hgcAB sequences found in nature, reducing degeneracy and providing increased sensitivity while maintaining broad diversity capture. We evaluated mock communities to confirm primer improvements, including culture spikes to environmental samples with variable DNA extraction and PCR amplification efficiencies. For select sites, this new workflow was combined with direct high-throughput hgcAB sequencing. The hgcAB diversity generated by direct amplicon sequencing confirmed the potential for novel Hg-methylators previously identified using metagenomic screens. A new phylogenetic analysis using sequences from freshwater, saline, and terrestrial environments showed Deltaproteobacteria HgcA sequences generally clustered among themselves, while metagenome-resolved HgcA sequences in other phyla tended to cluster by environment, suggesting horizontal gene transfer into many clades. HgcA from marine metagenomes often formed distinct subtrees from those sequenced from freshwater ecosystems. Overall the majority of HgcA sequences branch from a cluster of HgcAB fused proteins related to Thermococci, Atribacteria (candidate division OP9), Aminicenantes (OP8), and Chloroflexi. The improved primer set and library, combined with direct amplicon sequencing, provide a significantly improved assessment of the abundance and diversity of hgcAB+ microbes in nature.

Published

2020

3. Transcriptional Control of hgcAB by an ArsR-Like Regulator in Pseudodesulfovibrio mercurii ND132

Author

Caitlin M. Gionfriddo, Ally Bullock Soren, Ann M. Wymore, D. Sean Hartnett, Mircea Podar, Jerry M. Parks, Dwayne A. Elias, and Cynthia C. Gilmour

Subjects

Ecology, Environmental Microbiology, Applied Microbiology and Biotechnology, Food Science, Biotechnology

Abstract

The hgcAB gene pair encodes mercury (Hg) methylation capability in a diverse group of microorganisms, but its evolution and transcriptional regulation remain unknown. Working from the possibility that the evolutionary function of HgcAB may not be Hg methylation, we test a possible link to arsenic resistance. Using model Hg methylator Pseudodesulfovibrio mercurii ND132, we evaluated transcriptional control of hgcAB by a putative ArsR encoded upstream and cotranscribed with hgcAB. This regulator shares homology with ArsR repressors of arsenic resistance and S-adenosylhomocysteine (SAH)-responsive regulators of methionine biosynthesis but is distinct from other ArsR/SahR proteins in P. mercurii. Using quantitative PCR (qPCR) and RNA sequencing (RNA-seq) transcriptome analyses, we confirmed this ArsR regulates hgcAB transcription and is responsive to arsenic and SAH. Additionally, RNA-seq indicated a possible link between hgcAB activity and arsenic transformations, with significant upregulation of other ArsR-regulated arsenic resistance operons alongside hgcAB. Interestingly, wild-type ND132 was less sensitive to As(V) (but not As(III)) than an hgcAB knockout strain, supporting the idea that hgcAB may be linked to arsenic resistance. Arsenic significantly impacted rates of Hg methylation by ND132; however, responses varied with culture conditions. Differences in growth and metabolic activity did not account for arsenic impacts on methylation. While arsenic significantly increased hgcAB expression, hgcAB gene and transcript abundance was not a good predictor of Hg methylation rates. Taken together, these results support the idea that Hg and As cycling are linked in P. mercurii ND132. Our results may hold clues to the evolution of hgcAB and the controls on Hg methylation in nature. IMPORTANCE This work reveals a link between microbial mercury methylation and arsenic resistance and may hold clues to the evolution of mercury methylation genes (hgcAB). Microbes with hgcAB produce methylmercury, a strong neurotoxin that readily accumulates in the food web. This study addresses a critical gap in our understanding about the environmental factors that control hgcAB expression. We show that hgcAB expression is controlled by an ArsR-like regulator responsive to both arsenic and S-adenosylhomocysteine in our model organism, Pseudodesulfovibrio mercurii ND132. Exposure to arsenic also significantly impacted Pseudodesulfovibrio mercurii ND132 mercury methylation rates. However, expression of hgcAB was not always a good predictor of Hg methylation rates, highlighting the roles of Hg bioavailability and other biochemical mechanisms in methylmercury production. This study improves our understanding of the controls on hgcAB expression, which is needed to better predict environmental methylmercury production.

Published

2023

4. Role of Ester Sulfate and Organic Disulfide in Mercury Methylation in Peatland Soils

Author

Caroline E. Pierce, Olha S. Furman, Sarah L. Nicholas, Jill Coleman Wasik, Caitlin M. Gionfriddo, Ann M. Wymore, Stephen D. Sebestyen, Randall K. Kolka, Carl P. J. Mitchell, Natalie A. Griffiths, Dwayne A. Elias, Edward A. Nater, and Brandy M. Toner

Subjects

Soil, Sulfates, Environmental Chemistry, Esters, Disulfides, Mercury, General Chemistry, Methylmercury Compounds, Methylation

Abstract

We examined the composition and spatial correlation of sulfur and mercury pools in peatland soil profiles by measuring sulfur speciation by 1s X-ray absorption near-edge structure spectrocopy and mercury concentrations by cold vapor atomic fluorescence spectroscopy. Also investigated were the methylation/demethylation rate constants and the presence of

Published

2022

5. Transcriptional control ofhgcABby an ArsR-like regulator inPseudodesulfovibrio mercuriiND132

Author

Caitlin M. Gionfriddo, Ally Bullock Soren, Ann Wymore, D. Sean Hartnett, Mircea Podar, Jerry M. Parks, Dwayne A. Elias, and Cynthia C. Gilmour

Abstract

ThehgcABgene pair encodes mercury (Hg) methylation capability in a diverse group of microorganisms, but its evolution and transcriptional regulation remain unknown. Working from the possibility that the evolutionary function of HgcAB may not be Hg methylation, we test a possible link to arsenic resistance. Using model Hg-methylatorPseudodesulfovibrio mercuriiND132, we specifically evaluated transcriptional control ofhgcABby a putative ArsR encoded upstream and co-transcribed withhgcAB. This regulator shares homology with ArsR repressors of arsenic resistance and S-adenosyl-homocysteine (SAH) responsive regulators of methionine biosynthesis but is distinct from other ArsR/SahR inPseudodesulfovibrio mercuriiND132. Using qPCR and RNA-seq analyses we confirmed this ArsR regulateshgcABtranscription, and is responsive to arsenic and SAH. Additionally, RNA-seq indicated a possible link betweenhgcABactivity and arsenic transformations byPseudodesulfovibrio mercuriiND132, with significant up-regulation of other ArsR-regulated arsenic resistance operons alongsidehgcAB. Interestingly, wild-type ND132 was less sensitive to AsV (but not AsIII) than anhgcABknockout strain, supporting the idea thathgcABmay be linked to arsenic resistance. Arsenic significantly impacted Hg-methylation rates by ND132, however, responses varied with culture conditions. Differences in growth and overall metabolic activity did not account for arsenic impacts on methylation. One goal of this research is to better predict MeHg production in nature. However, we found thathgcABgene and transcript abundance was not a good predictor of Hg-methylation rates. Our finding thathgcABactivity is linked to arsenic may hold clues to the possible environmental drivers of horizontal transfer ofhgcAB.IMPORTANCEThis work reveals a link between microbial mercury methylation and arsenic resistance and may hold clues to the evolution of mercury methylation genes (hgcAB). Microbes withhgcABproduce methylmercury, a strong neurotoxin that readily accumulates in the food web. This study addresses a critical gap in our understanding about the environmental factors that controlhgcABexpression. We show thathgcABexpression is controlled by an ArsR-like regulator responsive to both arsenic and S-adenosyl-homocysteine in our model organism,Pseudodesulfovibrio mercuriiND132. Exposure to arsenic also significantly impactedPseudodesulfovibrio mercuriiND132 mercury methylation rates. However, expression ofhgcABwas not always a good predictor of Hg methylation rates, highlighting the roles of Hg bioavailability and other biochemical mechanisms in methylmercury production. This study improves our understanding of the controls onhgcABexpression which is needed to better predict environmental methylmercury production.

Published

2022

6. Mercury methylation by metabolically versatile and cosmopolitan marine bacteria

Author

John W. Moreau, David B. Ascher, Heyu Lin, Steven J. Hallam, Caitlin M. Gionfriddo, Yoochan Myung, Kathryn E. Holt, and Carl H. Lamborg

Subjects

Water microbiology, Microorganism, 010501 environmental sciences, Biology, Methylation, 01 natural sciences, Microbiology, Article, Microbial ecology, 03 medical and health sciences, chemistry.chemical_compound, Marine bacteriophage, Gene expression, Humans, Methylmercury, Gene, Ecosystem, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0105 earth and related environmental sciences, chemistry.chemical_classification, 0303 health sciences, Bacteria, British Columbia, Mercury, Biogeochemistry, biology.organism_classification, Amino acid, Biochemistry, chemistry, Structural biology, Water Pollutants, Chemical

Abstract

Microbes transform aqueous mercury (Hg) into methylmercury (MeHg), a potent neurotoxin that accumulates in terrestrial and marine food webs, with potential impacts on human health. This process requires the gene pair hgcAB, which encodes for proteins that actuate Hg methylation, and has been well described for anoxic environments. However, recent studies report potential MeHg formation in suboxic seawater, although the microorganisms involved remain poorly understood. In this study, we conducted large-scale multi-omic analyses to search for putative microbial Hg methylators along defined redox gradients in Saanich Inlet, British Columbia, a model natural ecosystem with previously measured Hg and MeHg concentration profiles. Analysis of gene expression profiles along the redoxcline identified several putative Hg methylating microbial groups, including Calditrichaeota, SAR324 and Marinimicrobia, with the last the most active based on hgc transcription levels. Marinimicrobia hgc genes were identified from multiple publicly available marine metagenomes, consistent with a potential key role in marine Hg methylation. Computational homology modelling predicts that Marinimicrobia HgcAB proteins contain the highly conserved amino acid sites and folding structures required for functional Hg methylation. Furthermore, a number of terminal oxidases from aerobic respiratory chains were associated with several putative novel Hg methylators. Our findings thus reveal potential novel marine Hg-methylating microorganisms with a greater oxygen tolerance and broader habitat range than previously recognized.

Published

2021

7. Determining the Reliability of Measuring Mercury Cycling Gene Abundance with Correlations with Mercury and Methylmercury Concentrations

Author

Steven D. Brown, Ann M. Wymore, Anthony V. Palumbo, Caitlin M. Gionfriddo, Judy D. Wall, Matthew W. Fields, Heather M. Brewer, Chiachi Hwang, Andrew J. King, Cynthia C. Gilmour, Scott C. Brooks, James G. Moberly, Mircea Podar, Geoff A. Christensen, Stephen J. Callister, Dwayne A. Elias, Anil C. Somenahally, Craig C. Brandt, and Carrie L. Miller

Subjects

Mercury cycling, Reproducibility of Results, chemistry.chemical_element, Mercury, General Chemistry, Methylmercury Compounds, 010501 environmental sciences, 01 natural sciences, Mercury (element), chemistry.chemical_compound, chemistry, RNA, Ribosomal, 16S, Environmental chemistry, Bioaccumulation, Environmental Chemistry, Ecosystem, Methylmercury, Environmental Monitoring, 0105 earth and related environmental sciences

Abstract

Methylmercury (MeHg) is a bioaccumulative toxic contaminant in many ecosystems, but factors governing its production are poorly understood. Recent work has shown that the anaerobic microbial conversion of mercury (Hg) to MeHg requires the Hg-methylation genes

Published

2019

8. Metagenome-Assembled Genome Sequences of Novel Prokaryotic Species from the Mercury-Contaminated East Fork Poplar Creek, Oak Ridge, Tennessee, USA

Author

Scott C. Brooks, Dwayne A. Elias, Ann M. Wymore, Caitlin M. Gionfriddo, Mircea Podar, Michael Wells, Minjae Kim, and Regina L. Wilpiszeski

Subjects

0303 health sciences, Genome Sequences, chemistry.chemical_element, 010501 environmental sciences, 01 natural sciences, Genome, Mercury (element), 03 medical and health sciences, Immunology and Microbiology (miscellaneous), chemistry, Metagenomics, Botany, Genetics, Ridge (meteorology), Environmental science, Molecular Biology, 030304 developmental biology, 0105 earth and related environmental sciences

Abstract

We sequenced two metagenomes of sediments from the East Fork Poplar Creek in the Oak Ridge Reservation (Oak Ridge, TN), a natural stream that has been contaminated with Hg from upstream sources, and we reconstructed 28 metagenome-assembled genomes of novel prokaryotic species.

Published

2021

9. Nutrient Exposure Alters Microbial Composition, Structure, and Mercury Methylating Activity in Periphyton in a Contaminated Watershed

Author

Caitlin M. Gionfriddo, Melissa A. Cregger, Dwayne A. Elias, Alyssa A. Carrell, Dawn M. Klingeman, Ann M. Wymore, Scott C. Brooks, Katherine A. Muller, Grace E. Schwartz, and Regina L. Wilpiszeski

Subjects

Microbiology (medical), mercury, Microorganism, periphyton, lcsh:QR1-502, microbiome, 010501 environmental sciences, Biology, 01 natural sciences, Microbiology, lcsh:Microbiology, 03 medical and health sciences, Nutrient, Microbial mat, Microbiome, Periphyton, 030304 developmental biology, 0105 earth and related environmental sciences, Original Research, 0303 health sciences, Community, Ecology, Community structure, methylmercury, biology.organism_classification, nutrient addition, Proteobacteria

Abstract

The conversion of mercury (Hg) to monomethylmercury (MMHg) is a critical area of concern in global Hg cycling. Periphyton biofilms may harbor significant amounts of MMHg but little is known about the Hg-methylating potential of the periphyton microbiome. Therefore, we used high-throughput amplicon sequencing of the 16S rRNA gene, ITS2 region, and Hg methylation gene pair (hgcAB) to characterize the archaea/bacteria, fungi, and Hg-methylating microorganisms in periphyton communities grown in a contaminated watershed in East Tennessee (United States). Furthermore, we examined how nutrient amendments (nitrate and/or phosphate) altered periphyton community structure and function. We found that bacterial/archaeal richness in experimental conditions decreased in summer and increased in autumn relative to control treatments, while fungal diversity generally increased in summer and decreased in autumn relative to control treatments. Interestingly, the Hg-methylating communities were dominated by Proteobacteria followed by Candidatus Atribacteria across both seasons. Surprisingly, Hg methylation potential correlated with numerous bacterial families that do not contain hgcAB, suggesting that the overall microbiome structure of periphyton communities influences rates of Hg transformation within these microbial mats. To further explore these complex community interactions, we performed a microbial network analysis and found that the nitrate-amended treatment resulted in the highest number of hub taxa that also corresponded with enhanced Hg methylation potential. This work provides insight into community interactions within the periphyton microbiome that may contribute to Hg cycling and will inform future research that will focus on establishing mixed microbial consortia to uncover mechanisms driving shifts in Hg cycling within periphyton habitats.

Published

2021

10. Atmospheric mercury in the Latrobe Valley, Australia: Case study June 2013

Author

Roger Dargaville, Caitlin M. Gionfriddo, Robyn Schofield, Mike Sandiford, Steven Utembe, Samuel B O Adeloju, Michael T. Tate, Melita Keywood, and David P. Krabbenhoft

Subjects

Atmospheric Science, Environmental Engineering, 010504 meteorology & atmospheric sciences, Ecology, Power station, business.industry, Diurnal temperature variation, Air pollution, chemistry.chemical_element, Geology, 010501 environmental sciences, Geotechnical Engineering and Engineering Geology, Oceanography, medicine.disease_cause, Atmospheric sciences, 01 natural sciences, Mercury (element), Electricity generation, chemistry, Diurnal cycle, medicine, Coal, business, Southern Hemisphere, 0105 earth and related environmental sciences

Abstract

Gaseous elemental mercury observations were conducted at Churchill, Victoria, in Australia from April to July, 2013, using a Tekran 2537 analyzer. A strong diurnal variation with daytime average values of 1.2–1.3 ng m–3 and nighttime average values of 1.6–1.8 ng m–3 was observed. These values are significantly higher than the Southern Hemisphere average of 0.85–1.05 ng m–3. Churchill is in the Latrobe Valley, approximately 150 km East of Melbourne, where approximately 80% of Victoria’s electricity is generated from low-rank brown coal from four major power stations: Loy Yang A, Loy Yang B, Hazelwood, and Yallourn. These aging generators do not have any sulfur, nitrogen oxide, or mercury air pollution controls. Mercury emitted in the 2015–2016 year in the Latrobe Valley is estimated to have had an externalized health cost of $AUD88 million. Air pollution mercury simulations were conducted using the Weather Research and Forecast model with Chemistry at 3 × 3 km resolution. Electrical power generation emissions were added using mercury emissions created from the National Energy Market’s 5-min energy distribution data. The strong diurnal cycle in the observed mercury was well simulated (R2 = .49 and P value = 0.00) when soil mercury emissions arising from several years of wet and dry deposition in a radius around the power generators was included in the model, as has been observed around aging lignite coal power generators elsewhere. These results indicate that long-term air and soil sampling in power generation regions, even after the closure of coal fired power stations, will have important implications to understanding the airborne mercury emissions sources.

Published

2021

11. Effects of syntrophic interactions on methyl-mercury generation

Author

Caitlin M. Gionfriddo, Regina L. Wilpiszeski, Ann M. Wymore, Dwayne A. Elias, and Mircea Podar

Subjects

Chemistry, Environmental chemistry, chemistry.chemical_element, Mercury (element)

Published

2021

12. Genome-Resolved Metagenomics and Detailed Geochemical Speciation Analyses Yield New Insights into Microbial Mercury Cycling in Geothermal Springs

Author

Ryan R. Wick, Matthew B. Stott, Caitlin M. Gionfriddo, David P. Krabbenhoft, Jean F. Power, Lin-Xing Chen, Jillian F. Banfield, John W. Moreau, Jacob M. Ogorek, Kathryn E. Holt, Brian C. Thomas, and Cann, Isaac

Subjects

Mercury cycling, mercury, chemistry.chemical_element, Microbiology, Hot Springs, biogeochemistry, geothermal, Genetics, Geothermal gradient, Life Below Water, metagenomics, Bacteria, Geothermal Springs, hgcAB, Human Genome, methylmercury, Archaea, Mercury (element), chemistry, Metagenomics, Environmental chemistry, merA, Environmental science, Metagenome, mercuric ion detoxification, New Zealand

Abstract

Geothermal systems emit substantial amounts of aqueous, gaseous, and methylated mercury, but little is known about microbial influences on mercury speciation. Here, we report results from genome-resolved metagenomics and mercury speciation analysis of acidic warm springs in the Ngawha Geothermal Field (

Published

2020

13. Mercury methylation by metabolically versatile and cosmopolitan marine bacteria

Author

Heyu Lin, Carl H. Lamborg, Caitlin M. Gionfriddo, Steven J. Hallam, Kathryn E. Holt, Yoochan Myung, John W. Moreau, and David B. Ascher

Subjects

chemistry.chemical_compound, Marine bacteriophage, chemistry, Biochemistry, Microorganism, Gene expression, chemistry.chemical_element, Methylation, Gene, Methylmercury, Anoxic waters, Mercury (element)

Abstract

Microbes transform aqueous mercury (Hg) into methylmercury (MeHg), a potent neurotoxin in terrestrial and marine food webs. This process requires the gene pair hgcAB, which encodes for proteins that actuate Hg methylation, and has been well described for anoxic environments. However, recent studies report potential MeHg formation in suboxic seawater, although the microorganisms involved remain poorly understood. In this study, we conducted large-scale multi-omic analyses to search for putative microbial Hg methylators along defined redox gradients in Saanich Inlet (SI), British Columbia, a model natural ecosystem with previously measured Hg and MeHg concentration profiles. Analysis of gene expression profiles along the redoxcline identified several putative Hg methylating microbial groups, including Calditrichaeota, SAR324 and Marinimicrobia, with the last by far the most active based on hgc transcription levels. Marinimicrobia hgc genes were identified from multiple publicly available marine metagenomes, consistent with a potential key role in marine Hg methylation. Computational homology modelling predicted that Marinimicrobia HgcAB proteins contain the highly conserved structures required for functional Hg methylation. Furthermore, a number of terminal oxidases from aerobic respiratory chains were associated with several SI putative novel Hg methylators. Our findings thus reveal potential novel marine Hg-methylating microorganisms with a greater oxygen tolerance and broader habitat range than previously recognised.

Published

2020

14. An Improved

Author

Caitlin M, Gionfriddo, Ann M, Wymore, Daniel S, Jones, Regina L, Wilpiszeski, Mackenzie M, Lynes, Geoff A, Christensen, Ally, Soren, Cynthia C, Gilmour, Mircea, Podar, and Dwayne A, Elias

Subjects

amplicon sequencing, hgcAB, microbial diversity, mercury methylation, environmental microbiology, Microbiology, primer development, Original Research

Abstract

The gene pair hgcAB is essential for microbial mercury methylation. Our understanding of its abundance and diversity in nature is rapidly evolving. In this study we developed a new broad-range primer set for hgcAB, plus an expanded hgcAB reference library, and used these to characterize Hg-methylating communities from diverse environments. We applied this new Hg-methylator database to assign taxonomy to hgcA sequences from clone, amplicon, and metagenomic datasets. We evaluated potential biases introduced in primer design, sequence length, and classification, and suggest best practices for studying Hg-methylator diversity. Our study confirms the emerging picture of an expanded diversity of HgcAB-encoding microbes in many types of ecosystems, with abundant putative mercury methylators Nitrospirae and Chloroflexi in several new environments including salt marsh and peat soils. Other common microbes encoding HgcAB included Phycisphaerae, Aminicenantes, Spirochaetes, and Elusimicrobia. Combined with high-throughput amplicon specific sequencing, the new primer set also indentified novel hgcAB sequences similar to Lentisphaerae, Bacteroidetes, Atribacteria, and candidate phyla WOR-3 and KSB1 bacteria. Gene abundance data also corroborate the important role of two “classic” groups of methylators (Deltaproteobacteria and Methanomicrobia) in many environments, but generally show a scarcity of hgcAB+ Firmicutes. The new primer set was developed to specifically target hgcAB sequences found in nature, reducing degeneracy and providing increased sensitivity while maintaining broad diversity capture. We evaluated mock communities to confirm primer improvements, including culture spikes to environmental samples with variable DNA extraction and PCR amplification efficiencies. For select sites, this new workflow was combined with direct high-throughput hgcAB sequencing. The hgcAB diversity generated by direct amplicon sequencing confirmed the potential for novel Hg-methylators previously identified using metagenomic screens. A new phylogenetic analysis using sequences from freshwater, saline, and terrestrial environments showed Deltaproteobacteria HgcA sequences generally clustered among themselves, while metagenome-resolved HgcA sequences in other phyla tended to cluster by environment, suggesting horizontal gene transfer into many clades. HgcA from marine metagenomes often formed distinct subtrees from those sequenced from freshwater ecosystems. Overall the majority of HgcA sequences branch from a cluster of HgcAB fused proteins related to Thermococci, Atribacteria (candidate division OP9), Aminicenantes (OP8), and Chloroflexi. The improved primer set and library, combined with direct amplicon sequencing, provide a significantly improved assessment of the abundance and diversity of hgcAB+ microbes in nature.

Published

2020

15. Genome-Resolved Investigation of Potential New Mercury-Methylating Marine Bacterial Phyla

Author

Heyu Lin, David B Ascher, Yoochan Myung, Carl H Lamborg, Steven J Hallam, Caitlin M Gionfriddo, Ryan R Wick, Kathryn E Holt, and John W Moreau

Published

2020

16. A System Biology Approach to Discern the Native Biochemical Function of Hg Methylation Proteins in Desulfovibrio desulfuricans ND132

Author

Caitlin M Gionfriddo, Ann Wymore, Mircea Podar, Cynthia Gilmour, Allyson Soren, Regina Wilpiszeski, and Dwayne Elias

Published

2020

17. Resolving the Molecular Mechanisms Essential to Expression of hgcA by Mercury Methylators

Author

Caitlin M Gionfriddo, Ann Wymore, Regina Wilpiszeski, Grace Schwartz, Cynthia Gilmour, and Dwayne Elias

Published

2020

18. Pseudodesulfovibrio mercurii sp. nov., a mercury-methylating bacterium isolated from sediment

Author

Judy D. Wall, Caitlin M. Gionfriddo, Dwayne A. Elias, Mircea Podar, Maria Soledad Goñi Urriza, Ally Soren, Joshua K. Michener, Steven D. Brown, Cynthia C. Gilmour, Smithsonian Environmental Research Center, Smithsonian Institution, Institut des sciences analytiques et de physico-chimie pour l'environnement et les materiaux (IPREM), Université de Pau et des Pays de l'Adour (UPPA)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Oak Ridge National Laboratory [Oak Ridge] (ORNL), UT-Battelle, LLC, and ANR-16-IDEX-0002,E2S,E2S(2016)

Subjects

0301 basic medicine, 010501 environmental sciences, Deltaproteobacteria, 01 natural sciences, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, [CHIM]Chemical Sciences, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, [SDV.EE]Life Sciences [q-bio]/Ecology, environment, Phylogenetic tree, biology, Strain (chemistry), Incomplete oxidizer, Methylmercury, General Medicine, 16S ribosomal RNA, biology.organism_classification, genomic DNA, 030104 developmental biology, Biochemistry, chemistry, Sulfate-reducer, DNA, Bacteria, Mesophile

Abstract

The sulfate-reducing, mercury-methylating strain ND132T was isolated from the brackish anaerobic bottom sediments of Chesapeake Bay, USA. Capable of high levels of mercury (Hg) methylation, ND132T has been widely used as a model strain to study the process and to determine the genetic basis of Hg methylation. Originally called Desulfovibrio desulfuricans ND132T on the basis of an early partial 16S rRNA sequence, the strain has never been formally described. Phylogenetic and physiological traits place this strain within the genus Pseudodesulfovibrio, in the recently reclassified phylum Desulfobacterota (formerly Deltaproteobacteria ). ND132T is most closely related to Pseudodesulfovibrio hydrargyri BerOc1T and Pseudodesulfovibrio indicus J2T. Analysis of average nucleotide identity (ANI) of whole-genome sequences showed roughly 88 % ANI between P. hydrargyri BerOc1T and ND132T, and 84 % similarity between ND132T and P. indicus J2T. These cut-off scores Desulfovibrionacea, and differences in physiology indicate that all three strains represent separate species. The Gram-stain-negative cells are vibrio-shaped, motile and not sporulated. ND132T is a salt-tolerant mesophile with optimal growth in the laboratory at 32 °C, 2 % salinity, and pH 7.8. The DNA G+C content of the genomic DNA is 65.2 %. It is an incomplete oxidizer of short chain fatty acids, using lactate, pyruvate and fumarate with sulfate or sulfite as the terminal electron acceptors. ND132T can respire fumarate using pyruvate as an electron donor. The major fatty acids are iso-C15 : 0, anteiso-C15 : 0, iso-C17 : 0, iso-C17 : 1ω9c and anteiso-C17 : 0. We propose the classification of strain ND132T (DSM 110689, ATCC TSD-224) as the type strain Pseudodesulfovibrio mercurii sp. nov.

Published

2019

19. Boundary layer new particle formation over East Antarctic sea ice – possible Hg-driven nucleation?

Author

David P. Krabbenhoft, Caitlin M. Gionfriddo, Melita Keywood, Ian E. Galbally, Robyn Schofield, Suzie B. Molloy, Michael T. Tate, Neil R. P. Harris, Jeffrey R. Pierce, Andrew Robinson, Ruhi S Humphries, Andrew R. Klekociuk, Robert Johnson, Karin Kreher, Paul Johnston, A. Thomas, Stephen R. Wilson, and J Ward

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Northern Hemisphere, Nucleation, Antarctic sea ice, Atmospheric sciences, Arctic ice pack, lcsh:QC1-999, Aerosol, lcsh:Chemistry, Troposphere, chemistry.chemical_compound, lcsh:QD1-999, chemistry, Sea ice, Environmental science, Dimethyl sulfide, lcsh:Physics

Abstract

Aerosol observations above the Southern Ocean and Antarctic sea ice are scarce. Measurements of aerosols and atmospheric composition were made in East Antarctic pack ice on board the Australian icebreaker Aurora Australis during the spring of 2012. One particle formation event was observed during the 32 days of observations. This event occurred on the only day to exhibit extended periods of global irradiance in excess of 600 W m−2. Within the single air mass influencing the measurements, number concentrations of particles larger than 3 nm (CN3) reached almost 7700 cm−3 within a few hours of clouds clearing, and grew at rates of 5.6 nm h−1. Formation rates of 3 nm particles were in the range of those measured at other Antarctic locations at 0.2–1.1 ± 0.1 cm−3 s−1. Our investigations into the nucleation chemistry found that there were insufficient precursor concentrations for known halogen or organic chemistry to explain the nucleation event. Modelling studies utilising known sulfuric acid nucleation schemes could not simultaneously reproduce both particle formation or growth rates. Surprising correlations with total gaseous mercury (TGM) were found that, together with other data, suggest a mercury-driven photochemical nucleation mechanism may be responsible for aerosol nucleation. Given the very low vapour pressures of the mercury species involved, this nucleation chemistry is likely only possible where pre-existing aerosol concentrations are low and both TGM concentrations and solar radiation levels are relatively high (∼ 1.5 ng m−3 and ≥ 600 W m−2, respectively), such as those observed in the Antarctic sea ice boundary layer in this study or in the global free troposphere, particularly in the Northern Hemisphere.

Published

2015

20. Quantification of Mercury Bioavailability for Methylation Using Diffusive Gradient in Thin-Film Samplers

Author

Heileen Hsu-Kim, Udonna Ndu, Geoff A. Christensen, Dwayne A. Elias, Caitlin M. Gionfriddo, Marc A. Deshusses, and Nelson Rivera

Subjects

0301 basic medicine, Geologic Sediments, chemistry.chemical_element, Biological Availability, 010501 environmental sciences, 01 natural sciences, Methylation, Article, 03 medical and health sciences, chemistry.chemical_compound, Environmental Chemistry, Water pollution, Methylmercury, 0105 earth and related environmental sciences, chemistry.chemical_classification, Chemistry, General Chemistry, Glutathione, Mercury, Methylmercury Compounds, Mercury (element), Bioavailability, 030104 developmental biology, 13. Climate action, Environmental chemistry, Bioaccumulation, Thiol, Microcosm, Water Pollutants, Chemical

Abstract

Mercury-contaminated sediment and water contain various Hg species, with a small fraction available for microbial conversion to the bioaccumulative neurotoxin monomethylmercury (MeHg). Quantification of this available Hg pool is needed to prioritize sites for risk management. This study compared the efficacy of diffusive gradient in thin-film (DGT) passive samplers to a thiol-based selective extraction method with glutathione (GSH) and conventional filtration (

Published

2018

21. Mercury distribution and mobility at the abandoned Puhipuhi mercury mine, Northland, New Zealand

Author

David P. Krabbenhoft, Caitlin M. Gionfriddo, John W. Moreau, M Butcher, and Jacob M. Ogorek

Subjects

Environmental remediation, Sediment, chemistry.chemical_element, Geology, Mercury (element), chemistry.chemical_compound, Geophysics, chemistry, Cinnabar, Mining engineering, Environmental chemistry, Soil water, Earth and Planetary Sciences (miscellaneous), Environmental impact assessment, Mercury contamination, Methylmercury

Abstract

The United Nations 2013 Minamata Convention advocates for updated environmental assessments of potential point-source sites of mercury contamination, including historic closed or abandoned mines. The Puhipuhi mercury mine (Northland), a historic and abandoned mine site, is located near one of the headwaters of the Wairoa River. In this study, total mercury levels in soils and sediments (37.8–1748 µg g−1), total and methylated mercury in waters (69.6–240 ng L−1 and 0.637–1.95 ng L−1, respectively), and elemental mercury in air (0.06–0.5 ng m−3) were measured to assess the probability and form of mercury release from the site to the surrounding natural environment. Results showed that mercury concentrations at the site are elevated compared to regional backgrounds and further work is necessary to determine how mercury may be transported from the site.

Published

2015

22. Microbial mercury methylation in Antarctic sea ice

Author

Caitlin M. Gionfriddo, Michael P. Thelen, Kathryn E. Holt, Ryan R. Wick, John W. Moreau, Mark B. Schultz, Michael T. Tate, Robyn Schofield, David P. Krabbenhoft, and Adam Zemla

Subjects

Microbiology (medical), 010504 meteorology & atmospheric sciences, Microbial DNA, Microbial Consortia, Immunology, Antarctic Regions, chemistry.chemical_element, Antarctic sea ice, 010501 environmental sciences, Bacterial Physiological Phenomena, Methylation, 01 natural sciences, Applied Microbiology and Biotechnology, Microbiology, Snow, Genetics, Sea ice, Cryosphere, Ice Cover, Seawater, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Bacteria, Mercury, Cell Biology, Methylmercury Compounds, Mercury (element), Fishery, chemistry, Environmental chemistry, Bioaccumulation, Environmental science, Metagenomics, Anaerobic bacteria

Abstract

Atmospheric deposition of mercury onto sea ice and circumpolar sea water provides mercury for microbial methylation, and contributes to the bioaccumulation of the potent neurotoxin methylmercury in the marine food web. Little is known about the abiotic and biotic controls on microbial mercury methylation in polar marine systems. However, mercury methylation is known to occur alongside photochemical and microbial mercury reduction and subsequent volatilization. Here, we combine mercury speciation measurements of total and methylated mercury with metagenomic analysis of whole-community microbial DNA from Antarctic snow, brine, sea ice and sea water to elucidate potential microbially mediated mercury methylation and volatilization pathways in polar marine environments. Our results identify the marine microaerophilic bacterium Nitrospina as a potential mercury methylator within sea ice. Anaerobic bacteria known to methylate mercury were notably absent from sea-ice metagenomes. We propose that Antarctic sea ice can harbour a microbial source of methylmercury in the Southern Ocean.

Published

2016

23. The Effect of Natural Organic Matter on Mercury Methylation by Desulfobulbus propionicus 1pr3

Author

David P. Krabbenhoft, Jacob M. Ogorek, Caitlin M. Gionfriddo, Eric E. Roden, John F. DeWild, George R. Aiken, and John W. Moreau

Subjects

Microbiology (medical), biology, Ecology, lcsh:QR1-502, chemistry.chemical_element, methylmercury, Methylation, biology.organism_classification, Microbiology, lcsh:Microbiology, Mercury (element), Bioavailability, chemistry.chemical_compound, chemistry, Desulfobulbus propionicus, mercury isotopes, TRACER, Environmental chemistry, Dissolved organic carbon, mercury methylation, sulfate-reducing bacteria, Sulfate-reducing bacteria, natural organic matter, Methylmercury, Original Research

Abstract

Methylation of tracer and ambient mercury (200Hg and 202Hg, respectively) equilibrated with four different natural organic matter (NOM) isolates was investigated in vivo using the Hg-methylating sulfate-reducing bacterium Desulfobulbus propionicus 1pr3. Desulfobulbus cultures grown fermentatively with environmentally representative concentrations of dissolved NOM isolates, Hg[II], and HS-, were assayed for absolute methylmercury (MeHg) concentration and conversion of Hg(II) to MeHg relative to total unfiltered Hg(II). Results showed the 200Hg tracer was methylated more efficiently in the presence of hydrophobic NOM isolates than in the presence of transphilic NOM, or in the absence of NOM. Different NOM isolates were associated with variable methylation efficiencies for either the 202Hg tracer or ambient 200Hg. One hydrophobic NOM, F1 HpoA derived from dissolved organic matter from the Florida Everglades, was equilibrated for different times with Hg tracer, which resulted in different methylation rates. A five-day equilibration with F1 HpoA resulted in more MeHg production than either the four-hour or thirty-day equilibration periods, suggesting a time dependence for NOM-enhanced Hg bioavailability for methylation.

Published

2015

24. In-field bioreactors demonstrate dynamic shifts in microbial communities in response to geochemical perturbations.

Author

Regina L Wilpiszeski, Caitlin M Gionfriddo, Ann M Wymore, Ji-Won Moon, Kenneth A Lowe, Mircea Podar, Sa'ad Rafie, Matthew W Fields, Terry C Hazen, Xiaoxuan Ge, Farris Poole, Michael W W Adams, Romy Chakraborty, Yupeng Fan, Joy D Van Nostrand, Jizhong Zhou, Adam P Arkin, and Dwayne A Elias

Subjects

Medicine, Science

Abstract

Subsurface microbial communities mediate the transformation and fate of redox sensitive materials including organic matter, metals and radionuclides. Few studies have explored how changing geochemical conditions influence the composition of groundwater microbial communities over time. We temporally monitored alterations in abiotic forces on microbial community structure using 1L in-field bioreactors receiving background and contaminated groundwater at the Oak Ridge Reservation, TN. Planktonic and biofilm microbial communities were initialized with background water for 4 days to establish communities in triplicate control reactors and triplicate test reactors and then fed filtered water for 14 days. On day 18, three reactors were switched to receive filtered groundwater from a contaminated well, enriched in total dissolved solids relative to the background site, particularly chloride, nitrate, uranium, and sulfate. Biological and geochemical data were collected throughout the experiment, including planktonic and biofilm DNA for 16S rRNA amplicon sequencing, cell counts, total protein, anions, cations, trace metals, organic acids, bicarbonate, pH, Eh, DO, and conductivity. We observed significant shifts in both planktonic and biofilm microbial communities receiving contaminated water. This included a loss of rare taxa, especially amongst members of the Bacteroidetes, Acidobacteria, Chloroflexi, and Betaproteobacteria, but enrichment in the Fe- and nitrate- reducing Ferribacterium and parasitic Bdellovibrio. These shifted communities were more similar to the contaminated well community, suggesting that geochemical forces substantially influence microbial community diversity and structure. These influences can only be captured through such comprehensive temporal studies, which also enable more robust and accurate predictive models to be developed.

Published

2020

25. The Effect of Natural Organic Matter on Mercury Methylation by Desulfobulbus propionicus 1pr3

Author

John W Moreau, Caitlin M Gionfriddo, David P Krabbenhoft, Jacob M Ogorek, John F DeWild, George R Aiken, and Eric E Roden

Subjects

Mercury Isotopes, Natural organic matter, sulfate-reducing bacteria, methylmercury, Mercury methylation, Microbiology, QR1-502

Abstract

Methylation of tracer and ambient mercury (200Hg and 202Hg, respectively) equilibrated with four different natural organic matter (NOM) isolates was investigated in vivo using the Hg-methylating sulfate-reducing bacterium Desulfobulbus propionicus 1pr3. Desulfobulbus cultures grown fermentatively with environmentally representative concentrations of dissolved NOM isolates, Hg[II], and HS-, were assayed for absolute methylmercury (MeHg) concentration and conversion of Hg(II) to MeHg relative to total unfiltered Hg(II). Results showed the 200Hg tracer was methylated more efficiently in the presence of hydrophobic NOM isolates than in the presence of transphilic NOM, or in the absence of NOM. Different NOM isolates were associated with variable methylation efficiencies for either the 202Hg tracer or ambient 200Hg. One hydrophobic NOM, F1 HpoA derived from dissolved organic matter from the Florida Everglades, was equilibrated for different times with Hg tracer, which resulted in different methylation rates. A five-day equilibration with F1 HpoA resulted in more MeHg production than either the four-hour or thirty-day equilibration periods, suggesting a time dependence for NOM-enhanced Hg bioavailability for methylation.

Published

2015