The Impact of Intensive Fish Farming on Pond Sediment Microbiome and Antibiotic Resistance Gene Composition

Lastauskienė, Eglė; Valskys, Vaidotas; Stankevičiūtė, Jonita; Kalcienė, Virginija; Gėgžna, Vilmantas; Kavoliūnas, Justinas; Ružauskas, Modestas; Armalytė, Julija

doi:10.3389/fvets.2021.673756

Cited by 23 publications

(15 citation statements)

References 53 publications

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“…Comparative studies on the land use effect on aquatic microbial communities have mostly been conducted on running water (rivers and streams) (Chen et al, 2018; Fasching et al, 2020; Le et al, 2018) or lakes (Marmen et al, 2020), revealing cases in which local land use has a stronger influence on community composition than upstream land use (Le et al, 2018). Microbiome studies on ponds in agricultural landscapes (e.g., Chopyk et al, 2018, 2020) or aquaculture (e.g., Lastauskienė et al, 2021) have been mostly focused on individual ponds.…”

Section: Introductionmentioning

confidence: 99%

From microbes to mammals: Pond biodiversity homogenization across different land‐use types in an agricultural landscape

Ionescu

Bižić

Karnatak

et al. 2022

Ecological Monographs

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Local biodiversity patterns are expected to strongly reflect variation in topography, land use, dispersal boundaries, nutrient supplies, contaminant spread, management practices, and other anthropogenic influences. Contrary to this expectation, studies focusing on specific taxa revealed a biodiversity homogenization effect in areas subjected to long-term intensive industrial agriculture. We investigated whether land use affects biodiversity levels and community composition (α-and β-diversity) in 67 kettle holes (KH) representing small aquatic islands embedded in the patchwork matrix of a largely agricultural landscape comprising grassland, forest, and arable fields. These KH, similar to millions of standing water bodies of glacial origin, spread across northern Europe, Asia, and North America, are physico-chemically diverse and differ in the degree of coupling with their surroundings. We assessed aquatic and sediment biodiversity patterns of eukaryotes, Bacteria, and Archaea in relation to environmental features of the KH, using deep-amplicon-sequencing of environmental DNA (eDNA). First, we asked whether deep sequencing of eDNA provides a representative picture of KH aquatic biodiversity across the Bacteria, Archaea, and eukaryotes. Second, we investigated if and to what extent KH biodiversity is influenced by the surrounding land use. We hypothesized that richness and community composition will greatly differ in KH from agricultural land use compared with KH in grasslands and forests. Our data show that deep eDNA amplicon sequencing is useful for in-depth assessments of cross-domain biodiversity comprising both micro-and macro-organisms, but has limitations with respect to single-taxa conservation studies. Using this broad method, we show that sediment eDNA, integrating several years to D. Ionescu and M. Bizic contributed equally to the work.

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Section: Introductionmentioning

confidence: 99%

From microbes to mammals: Pond biodiversity homogenization across different land‐use types in an agricultural landscape

Ionescu

Bižić

Karnatak

et al. 2022

Ecological Monographs

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“…The microbiota in aquaculture systems is an essential aspect of affecting the health status of farmed animals and evaluating system safety, which can reflect the health status of aquaculture systems to a certain extent [19,20]. A limited number of studies on microbiota in the IPRS have provided preliminary insights.…”

Section: Introductionmentioning

confidence: 99%

Interaction of Microbiota between Fish and the Environment of an In-Pond Raceway System in a Lake

et al. 2022

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Due to its ability to collect and remove aquaculture waste, an in-pond raceway system (IPRS) has been used to decrease the uncontrolled waste discharge in the traditional cage aquaculture method in large water bodies. However, when applied to large water bodies, its environmental performance is still lacking. This study focused on analyzing the microbial characteristics and the interaction between largemouth bass (gill and gut) microbiota and the environment (water and sediment) microbiota of an IPRS. Further, it revealed the primary relationship from the perspective of microbiota in the IPRS. The results show that (1) the alpha diversity of microbiota in the water is significantly lower than that of fish and sediment. The relationship between water microbiota and fish microbiota is limited. (2) The water microbiota inside and outside the tank showed high similarity and were not significantly affected by environmental factors. (3) The SourceTrack analysis showed that fish microbiota is one of the primary sources of sediment microbiota, and more than 15% of the sediment microbiota come from fish. Microbes such as Faecalibacterium, Escherichia-Shigella, and Bacteroides can significantly enrich the sediment. Our study revealed the characteristics and preliminary interaction of fish and environmental microbiota in the IPRS. It provided a reference for evaluating microbial health status in the application of IPRS in large water bodies’ aquaculture.

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“…Bottom sediments are composed of sedimentary material deposited on the bottom of rivers and water bodies. Fish ponds are rich in dissolved organic matter due to intensive feeding and fecal waste [ 10 ]. Ponds accumulate bottom sediments after their basins are formed under the influence of the water regime (emptying and filling).…”

Section: Introductionmentioning

confidence: 99%

“…Ponds accumulate bottom sediments after their basins are formed under the influence of the water regime (emptying and filling). These sediments are formed from biological debris originating from the ponds and their catchments, as well as soil particles and other non-biological materials that have entered the water body [ 10 ]. Cellulolytic bacteria, numerous anaerobic chemoautotrophs, and anaerobic microbiota typically thrive in bottom sediments [ 10 ].…”

Section: Introductionmentioning

confidence: 99%

“…These sediments are formed from biological debris originating from the ponds and their catchments, as well as soil particles and other non-biological materials that have entered the water body [ 10 ]. Cellulolytic bacteria, numerous anaerobic chemoautotrophs, and anaerobic microbiota typically thrive in bottom sediments [ 10 ]. In the Arctic sediments in Baffin Bay, Cramm, et al [ 11 ] noted the presence of putative methane-oxidizing Methyloprofundus , sulfate-reducing Desulfobulbaceae , and sulfide-oxidizing Sulfurovum .…”

Section: Introductionmentioning

confidence: 99%

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Functional and Seasonal Changes in the Structure of Microbiome Inhabiting Bottom Sediments of a Pond Intended for Ecological King Carp Farming

Wolińska

Kruczyńska

Grządziel

et al. 2022

Biology

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The main goal of the study was to determine changes in the bacterial structure in bottom sediments occurring over the seasons of the year and to estimate microbial metabolic activity. Bottom sediments were collected four times in the year (spring, summer, autumn, and winter) from 10 different measurement points in Cardinal Pond (Ślesin, NW Poland). The Next-Generation Sequencing (MiSeq Illumina) and Community-Level Physiological Profiling techniques were used for identification of the bacterial diversity structure and bacterial metabolic and functional activities over the four seasons. It was evident that Proteobacteria, Acidobacteria, and Bacteroidetes were the dominant phyla, while representatives of Betaproteobacteria, Gammaproteobacteria, and Deltaproteobacteria predominated at the class level in the bottom sediments. An impact of the season on biodiversity and metabolic activity was revealed with the emphasis that the environmental conditions in summer modified the studied parameters most strongly. Carboxylic and acetic acids and carbohydrates were metabolized most frequently, whereas aerobic respiration I with the use of cytochrome C was the main pathway used by the microbiome of the studied bottom sediments.

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The Impact of Intensive Fish Farming on Pond Sediment Microbiome and Antibiotic Resistance Gene Composition

Cited by 23 publications

References 53 publications

From microbes to mammals: Pond biodiversity homogenization across different land‐use types in an agricultural landscape

From microbes to mammals: Pond biodiversity homogenization across different land‐use types in an agricultural landscape

Interaction of Microbiota between Fish and the Environment of an In-Pond Raceway System in a Lake

Functional and Seasonal Changes in the Structure of Microbiome Inhabiting Bottom Sediments of a Pond Intended for Ecological King Carp Farming

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