Restructuring of the Aquatic Bacterial Community by Hydric Dynamics Associated with Superstorm Sandy

Ulrich, Nikea; Rosenberger, Abigail; Brislawn, Colin; Wright, Justin; Kessler, Collin; Toole, David R.; Solomon, Caroline; Strutt, Steven; McClure, Erin E.; Lamendella, Regina

doi:10.1128/aem.00520-16

Cited by 15 publications

(22 citation statements)

References 78 publications

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“…The fluctuations of major bacterial groups and functional genes during two large storm events (shown by PCR‐DGGE, high throughput sequencing, and qPCR in the results) indicated that changes occurred during the storms, but the differences in bacterial communities were likely due to shifts in the relative abundance of species rather than variation in presence/absence. Similar observations were made at Muddy Creek Run, a second‐order stream in Huntingdon, PA, during Super Storm Sandy (Ulrich et al, ). To my knowledge, this study is the first of kind investigating bacterial community shifts in two sequential storm events with couple days apart.…”

Section: Discussionsupporting

confidence: 71%

“…These allochthonous particulate organic sources serve as a critical energy supply for biota living in the streams and therefore contribute to ecosystem metabolism and energy flow within aquatic food webs (Tank et al, ). In addition to the massive amount of particulate materials, the storm events also mobilize abundant particle‐associated microorganisms, and “mixing and seeding” of these “new” microorganisms could lead to significant changes on the composition and distribution of microorganisms in receiving streams (Staley et al, ; Ulrich et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…Long‐term monitoring data in Upper Mississippi River showed that along with temperature and nutrient concentrations, rainfall was one of the major driving factors in shaping the bacterial community structure (Staley et al, ). Following Superstorm Sandy, Ulrich et al () demonstrated that large storm events significantly restructured in‐stream bacterial communities. However, high heterogeneity and variability in water column microbiota (Staley et al, ) highlighted the need for more detailed investigations on the temporal variation of aquatic microbial composition during a storm event.…”

Section: Introductionmentioning

confidence: 99%

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Storm Events Restructured Bacterial Community and Their Biogeochemical Potentials

Kan

2018

JGR Biogeosciences

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Large rainstorms deliver significant amounts of upland materials to headwater streams, thereby introducing the particle-associated microorganisms from complex soil environments into stream networks. "Seeding and mixing" from terrestrial sources may generate "new" in-stream microbial consortia and facilitate nutrient transformations and export to receiving waters. In order to investigate how large storm events influence the microbial community, bacterial community structure from White Clay Creek (Chester Co., PA, USA) was characterized following the Hurricane Irene and the Tropical Storm Lee. High-throughput sequencing of the 16S rRNA genes was used to track changes of bacterial community before, during, and after the events. Detailed bacterial community structures based on analyses of 3,004,072 sequences indicated an increase of bacterial diversity during peak discharge of the storm. Significant successional changes of bacterial community structure during the events were observed: Betaproteobacteria decreased in relative abundance, while members of Deltaproteobacteria, Acidobacteria, Chloroflexi, Nitrospirae, Planctomycetes, and Verrucomicrobia increased with the discharge suggesting potential impacts from terrestrial inputs and re-suspended sediments. Cyanobacteria bloomed after the storm events, indicating that photosynthesis was one of the primary recovering processes. Real-time polymerase chain reaction (quantitative polymerase chain reaction) analyses on functional genes (amoA for nitrification and nirS/nirK for denitrification) suggested that storm events also changed the functional perspectives of the microbial communities, with the potential for alteration of subsequent biogeochemical transformations. Thus, large storm events inoculate microbes from terrestrial and streambeds to headwaters, and downslope dispersal ("mass-effect") and "species-sorting" likely restructure the microbial community as well as potential nutrient cycling.

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Section: Discussionsupporting

confidence: 71%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Storm Events Restructured Bacterial Community and Their Biogeochemical Potentials

Kan

2018

JGR Biogeosciences

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“…The V4 region of the 16s rrn genes from bacterial DNAs were amplified by Illumina tag (itag) PCR using the 515F forward primer and the Illumina 806R reverse barcoded primer (16S Illumina Amplicon Protocol, http://www.earthmicrobiome.org). Individual barcoded samples were prepared and sequenced (Ulrich et al., ) by Wright Labs (Huntingdon, PA).…”

Section: Methodsmentioning

confidence: 99%

A seasonal study of a passive abandoned coalmine drainage remediation system reveals three distinct zones of contaminant levels and microbial communities

Valkanas

Trun

2018

MicrobiologyOpen

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A passive remediation system that treats coalmine drainage was sampled to determine the impact seasonal changes had on water quality and microbial diversity. Every quarter for 1 year, water‐soil slurries were collected at the influent of the 5 settling ponds and the wetlands, and the effluent of the system. The concentration of 12 metals and sulfate, as well as sequences from the V4 region of the bacterial 16S rrn genes were determined. The water quality analysis revealed high levels of iron and sulfate, and measurable levels of Al, Ba, Cu, Pb, Mn, Sr, and Zn. Iron increased 25‐fold in the summer and spikes in metal concentrations were observed during several seasons in pond 3 and the wetlands. These spikes cannot be explained by abiotic chemical reactions in the neutral pH found in the pond. Based on contaminant levels and microbial community composition, our results indicate that there were 3 unique environments in the system (ponds 1 and 2; pond 3; pond 4 through the end) and that changes in contaminant levels and bacterial composition in these environments correlated with seasonal variation. Iron and sulfate are the most prevalent contaminants in the system. An examination of sequences from known iron‐ and sulfur‐cycling bacteria demonstrated that there were more iron‐reducing (IRB) bacterial sequences than iron‐oxidizing (IOB) (137,912 IRB vs. 98,138 IOB), the two groups of bacteria were found mainly in the fall and winter samples, and were prevalent in different ponds. There were more sulfur/sulfide‐oxidizing (SOB) bacterial sequences than sulfur/sulfate‐reducing (SRB) bacterial sequences (72,978 SOB vs 30,504 SRB), they were found mainly in the fall and winter samples, and the sequences were mixed in ponds 4, 5 and the wetlands effluent. Iron is remediated in this system but sulfate is not.

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“…Microbiota are the base of biogeochemical cycles [9] and act as a pollutant biodegradation, so it is essential to assess a microbial community structure's changing nature in aquatic systems. The structures of bacterial communities are affected by the hydrodynamics of storm events [10], physiochemical parameters, longitudinal distance, upstream inputs affects and fecal indicator bacteria concentrations. Further, bacterivory, substrate availability, variation in hydrological and nutrient conditions [11], land use changes, distance from the pristine headwaters, rainfall and pH [12] influence the structure of microbial communities in riverine environments.…”

Section: Introductionmentioning

confidence: 99%

Spatial Modelling of Bacterial Diversity over the Selected Regions in Bangladesh by Next-Generation Sequencing: Role of Water Temperature

et al. 2020

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In this study, a spatial model has been developed to investigate the role of water temperature to the distribution of bacteria over the selected regions in the Bay of Bengal, located in the southern region of Bangladesh using next-generation sequencing. Bacterial concentration, quantitative polymerase chain reactions, and sequencing were performed on water samples and identified Acidobacteria, Actinobacteria, Bacteroidetes, Chlorobi, Chloroflexi, Cyanobacteria, Firmicutes, Nitrospirae, Planctomycetes, Proteobacteria, and Verrucomicrobia. The spatial model tessellated the parts of the Bay of Bengal with hexagons and analyzed the relationship between the distribution of bacteria and water temperature. A geographically weighted regression was used to observe whether water temperature contributed strongly or weakly to the distribution of bacteria. The residuals were examined to assess the model's fitness. The spatial model has the potential to predict the bacterial diversity in the selected regions of Bangladesh.

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Restructuring of the Aquatic Bacterial Community by Hydric Dynamics Associated with Superstorm Sandy

Cited by 15 publications

References 78 publications

Storm Events Restructured Bacterial Community and Their Biogeochemical Potentials

Storm Events Restructured Bacterial Community and Their Biogeochemical Potentials

A seasonal study of a passive abandoned coalmine drainage remediation system reveals three distinct zones of contaminant levels and microbial communities

Spatial Modelling of Bacterial Diversity over the Selected Regions in Bangladesh by Next-Generation Sequencing: Role of Water Temperature

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