Assessing biosynthetic potential of agricultural groundwater through metagenomic sequencing: A diverse anammox community dominates nitrate-rich groundwater

Autor: Thaddeus D. Seher, Joseph I. Kliegman, Olin Applegate, Edward R. Atwill, Joseph L. DeRisi, William B. Ludington, Thomas Harter, Xunde Li, Charles Langelier
Přispěvatelé: Yang, Shihui
Rok vydání: 2017
Předmět:
0301 basic medicine
Genomics Statistics
Thaumarchaeota
Microbial metabolism
lcsh:Medicine
Marine and Aquatic Sciences
Plant Science
Database and Informatics Methods
chemistry.chemical_compound
Nitrate
Crenarchaeota
lcsh:Science
Groundwater
Data Management
2. Zero hunger
Multidisciplinary
Bacterial Genomics
biology
Plant Bacterial Pathogens
Ecology
Microbial Genetics
Agriculture
Genomics
Genomic Databases
6. Clean water
Chemistry
Physical Sciences
Water Microbiology
Research Article
Lagoons
Computer and Information Sciences
Environmental remediation
General Science & Technology
030106 microbiology
Plant Pathogens
Microbial Genomics
Research and Analysis Methods
Microbiology
03 medical and health sciences
Genetics
Bacterial Genetics
Taxonomy
Nitrates
lcsh:R
Chemical Compounds
Biology and Life Sciences
Computational Biology
Bacteriology
Plant Pathology
Bodies of Water
Comparative Genomics
15. Life on land
Genome Analysis
biology.organism_classification
Biological Databases
030104 developmental biology
chemistry
13. Climate action
Metagenomics
Earth Sciences
lcsh:Q
Surface water
Zdroj: PloS one, vol 12, iss 4
PLoS ONE
Ludington, WB; Seher, TD; Applegate, O; Li, X; Kliegman, JI; Langelier, C; et al.(2017). Assessing biosynthetic potential of agricultural groundwater through metagenomic sequencing: A diverse anammox community dominates nitrate-rich groundwater. PLoS ONE, 12(4). doi: 10.1371/journal.pone.0174930. UC Davis: Retrieved from: http://www.escholarship.org/uc/item/2h11b468
PLoS ONE, Vol 12, Iss 4, p e0174930 (2017)
Popis: © 2017 Ludington et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Background: Climate change produces extremes in both temperature and precipitation causing increased drought severity and increased reliance on groundwater resources. Agricultural practices, which rely on groundwater, are sensitive to but also sources of contaminants, including nitrate. How agricultural contamination drives groundwater geochemistry through microbial metabolism is poorly understood. Methods: On an active cow dairy in the Central Valley of California, we sampled groundwater from three wells at depths of 4.3 m (two wells) and 100 m (one well) below ground surface (bgs) as well as an effluent surface water lagoon that fertilizes surrounding corn fields. We analyzed the samples for concentrations of solutes, heavy metals, and USDA pathogenic bacteria of the Escherichia coli and Enterococcus groups as part of a long term groundwater monitoring study. Whole metagenome shotgun sequencing and assembly revealed taxonomic composition and metabolic potential of the community. Results: Elevated nitrate and dissolved organic carbon occurred at 4.3m but not at 100m bgs. Metagenomics confirmed chemical observations and revealed several Planctomycete genomes, including a new Brocadiaceae lineage and a likely Planctomycetes OM190, as well novel diversity and high abundance of nano-prokaryotes from the Candidate Phyla Radiation (CPR), the Diapherotrites, Parvarchaeota, Aenigmarchaeota, Nanoarchaeota, Nanohaloarchaea (DPANN) and the Thaumarchaeota, Aigarchaeota, Crenarchaeota, Korarchaeota (TACK) superphyla. Pathway analysis suggests community interactions based on complimentary primary metabolic pathways and abundant secondary metabolite operons encoding antimicrobials and quorum sensing systems. Conclusions: The metagenomes show strong resemblance to activated sludge communities from a nitrogen removal reactor at a wastewater treatment plant, suggesting that natural bioremediation occurs through microbial metabolism. Elevated nitrate and rich secondary metabolite biosynthetic capacity suggest incomplete remediation and the potential for novel pharmacologically active compounds.
Databáze: OpenAIRE
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