Table_5_Anadromous Arctic Char Microbiomes: Bioprospecting in the High Arctic.pdf

Northern populations of Arctic char (Salvelinus alpinus) can be anadromous, migrating annually from the ocean to freshwater lakes and rivers in order to escape sub-zero temperatures. Such seasonal behavior demands that these fish and their associated microbiomes adapt to changes in salinity, tempera...

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Main Authors: Erin F. Hamilton, Geraint Element, Peter van Coeverden de Groot, Katja Engel, Josh D. Neufeld, Vishal Shah, Virginia K. Walker
Format: Dataset
Language:unknown
Published: 2019
Subjects:
Biotechnology
Biological Engineering
Genetic Engineering
Biomarkers
Biomaterials
Biomechanical Engineering
Biomedical Engineering not elsewhere classified
Synthetic Biology
Agricultural Marine Biotechnology
Bioremediation
Bioprocessing
Bioproduction and Bioproducts
Industrial Biotechnology Diagnostics (incl. Biosensors)
Industrial Microbiology (incl. Biofeedstocks)
Industrial Molecular Engineering of Nucleic Acids and Proteins
Industrial Biotechnology not elsewhere classified
Medical Biotechnology Diagnostics (incl. Biosensors)
Medical Molecular Engineering of Nucleic Acids and Proteins
Regenerative Medicine (incl. Stem Cells and Tissue Engineering)
Medical Biotechnology not elsewhere classified
Arctic char
salmonid fish
anadromous
microbiomes
bioprospecting
aquaculture
Arctic Ocean
aquatic biotechnology
Arctic
inuit
Salvelinus alpinus
Online Access:https://doi.org/10.3389/fbioe.2019.00032.s006
https://figshare.com/articles/Table_5_Anadromous_Arctic_Char_Microbiomes_Bioprospecting_in_the_High_Arctic_pdf/7768892
id ftfrontimediafig:oai:figshare.com:article/7768892
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spelling ftfrontimediafig:oai:figshare.com:article/7768892 2023-05-15T14:48:41+02:00 Table_5_Anadromous Arctic Char Microbiomes: Bioprospecting in the High Arctic.pdf Erin F. Hamilton Geraint Element Peter van Coeverden de Groot Katja Engel Josh D. Neufeld Vishal Shah Virginia K. Walker 2019-02-26T04:38:47Z https://doi.org/10.3389/fbioe.2019.00032.s006 https://figshare.com/articles/Table_5_Anadromous_Arctic_Char_Microbiomes_Bioprospecting_in_the_High_Arctic_pdf/7768892 unknown doi:10.3389/fbioe.2019.00032.s006 https://figshare.com/articles/Table_5_Anadromous_Arctic_Char_Microbiomes_Bioprospecting_in_the_High_Arctic_pdf/7768892 CC BY 4.0 CC-BY Biotechnology Biological Engineering Genetic Engineering Biomarkers Biomaterials Biomechanical Engineering Biomedical Engineering not elsewhere classified Synthetic Biology Agricultural Marine Biotechnology Bioremediation Bioprocessing Bioproduction and Bioproducts Industrial Biotechnology Diagnostics (incl. Biosensors) Industrial Microbiology (incl. Biofeedstocks) Industrial Molecular Engineering of Nucleic Acids and Proteins Industrial Biotechnology not elsewhere classified Medical Biotechnology Diagnostics (incl. Biosensors) Medical Molecular Engineering of Nucleic Acids and Proteins Regenerative Medicine (incl. Stem Cells and Tissue Engineering) Medical Biotechnology not elsewhere classified Arctic char salmonid fish anadromous microbiomes bioprospecting aquaculture Arctic Ocean aquatic biotechnology Dataset 2019 ftfrontimediafig https://doi.org/10.3389/fbioe.2019.00032.s006 2019-02-27T23:58:45Z Northern populations of Arctic char (Salvelinus alpinus) can be anadromous, migrating annually from the ocean to freshwater lakes and rivers in order to escape sub-zero temperatures. Such seasonal behavior demands that these fish and their associated microbiomes adapt to changes in salinity, temperature, and other environmental challenges. We characterized the microbial community composition of anadromous S. alpinus, netted by Inuit fishermen at freshwater and seawater fishing sites in the high Arctic, both under ice and in open water. Bacterial profiles were generated by DNA extraction and high-throughput sequencing of PCR-amplified 16S ribosomal RNA genes. Results showed that microbial communities on the skin and intestine of Arctic char were statistically different when sampled from freshwater or saline water sites. This association was tested using hierarchical Ward's linkage clustering, showing eight distinct clusters in each of the skin and intestinal microbiomes, with the clusters reflecting sampling location between fresh and saline environments, confirming a salinity-linked turnover. This analysis also provided evidence for a core composition of skin and intestinal bacteria, with the phyla Proteobacteria, Firmicutes, and Cyanobacteria presenting as major phyla within the skin-associated microbiomes. The intestine-associated microbiome was characterized by unidentified genera from families Fusobacteriaceae, Comamonadaceae, Pseudomonadaceae, and Vibrionaceae. The salinity-linked turnover was further tested through ordinations that showed samples grouping based on environment for both skin- and intestine-associated microbiomes. This finding implies that core microbiomes between fresh and saline conditions could be used to assist in regulating optimal fish health in aquaculture practices. Furthermore, identified taxa from known psychrophiles and with nitrogen cycling properties suggest that there is additional potential for biotechnological applications for fish farm and waste management practices. Dataset Arctic Arctic Ocean inuit Salvelinus alpinus Frontiers: Figshare Arctic Arctic Ocean
institution Open Polar
collection Frontiers: Figshare
op_collection_id ftfrontimediafig
language unknown
topic Biotechnology
Biological Engineering
Genetic Engineering
Biomarkers
Biomaterials
Biomechanical Engineering
Biomedical Engineering not elsewhere classified
Synthetic Biology
Agricultural Marine Biotechnology
Bioremediation
Bioprocessing
Bioproduction and Bioproducts
Industrial Biotechnology Diagnostics (incl. Biosensors)
Industrial Microbiology (incl. Biofeedstocks)
Industrial Molecular Engineering of Nucleic Acids and Proteins
Industrial Biotechnology not elsewhere classified
Medical Biotechnology Diagnostics (incl. Biosensors)
Medical Molecular Engineering of Nucleic Acids and Proteins
Regenerative Medicine (incl. Stem Cells and Tissue Engineering)
Medical Biotechnology not elsewhere classified
Arctic char
salmonid fish
anadromous
microbiomes
bioprospecting
aquaculture
Arctic Ocean
aquatic biotechnology
spellingShingle Biotechnology
Biological Engineering
Genetic Engineering
Biomarkers
Biomaterials
Biomechanical Engineering
Biomedical Engineering not elsewhere classified
Synthetic Biology
Agricultural Marine Biotechnology
Bioremediation
Bioprocessing
Bioproduction and Bioproducts
Industrial Biotechnology Diagnostics (incl. Biosensors)
Industrial Microbiology (incl. Biofeedstocks)
Industrial Molecular Engineering of Nucleic Acids and Proteins
Industrial Biotechnology not elsewhere classified
Medical Biotechnology Diagnostics (incl. Biosensors)
Medical Molecular Engineering of Nucleic Acids and Proteins
Regenerative Medicine (incl. Stem Cells and Tissue Engineering)
Medical Biotechnology not elsewhere classified
Arctic char
salmonid fish
anadromous
microbiomes
bioprospecting
aquaculture
Arctic Ocean
aquatic biotechnology
Erin F. Hamilton
Geraint Element
Peter van Coeverden de Groot
Katja Engel
Josh D. Neufeld
Vishal Shah
Virginia K. Walker
Table_5_Anadromous Arctic Char Microbiomes: Bioprospecting in the High Arctic.pdf
topic_facet Biotechnology
Biological Engineering
Genetic Engineering
Biomarkers
Biomaterials
Biomechanical Engineering
Biomedical Engineering not elsewhere classified
Synthetic Biology
Agricultural Marine Biotechnology
Bioremediation
Bioprocessing
Bioproduction and Bioproducts
Industrial Biotechnology Diagnostics (incl. Biosensors)
Industrial Microbiology (incl. Biofeedstocks)
Industrial Molecular Engineering of Nucleic Acids and Proteins
Industrial Biotechnology not elsewhere classified
Medical Biotechnology Diagnostics (incl. Biosensors)
Medical Molecular Engineering of Nucleic Acids and Proteins
Regenerative Medicine (incl. Stem Cells and Tissue Engineering)
Medical Biotechnology not elsewhere classified
Arctic char
salmonid fish
anadromous
microbiomes
bioprospecting
aquaculture
Arctic Ocean
aquatic biotechnology
description Northern populations of Arctic char (Salvelinus alpinus) can be anadromous, migrating annually from the ocean to freshwater lakes and rivers in order to escape sub-zero temperatures. Such seasonal behavior demands that these fish and their associated microbiomes adapt to changes in salinity, temperature, and other environmental challenges. We characterized the microbial community composition of anadromous S. alpinus, netted by Inuit fishermen at freshwater and seawater fishing sites in the high Arctic, both under ice and in open water. Bacterial profiles were generated by DNA extraction and high-throughput sequencing of PCR-amplified 16S ribosomal RNA genes. Results showed that microbial communities on the skin and intestine of Arctic char were statistically different when sampled from freshwater or saline water sites. This association was tested using hierarchical Ward's linkage clustering, showing eight distinct clusters in each of the skin and intestinal microbiomes, with the clusters reflecting sampling location between fresh and saline environments, confirming a salinity-linked turnover. This analysis also provided evidence for a core composition of skin and intestinal bacteria, with the phyla Proteobacteria, Firmicutes, and Cyanobacteria presenting as major phyla within the skin-associated microbiomes. The intestine-associated microbiome was characterized by unidentified genera from families Fusobacteriaceae, Comamonadaceae, Pseudomonadaceae, and Vibrionaceae. The salinity-linked turnover was further tested through ordinations that showed samples grouping based on environment for both skin- and intestine-associated microbiomes. This finding implies that core microbiomes between fresh and saline conditions could be used to assist in regulating optimal fish health in aquaculture practices. Furthermore, identified taxa from known psychrophiles and with nitrogen cycling properties suggest that there is additional potential for biotechnological applications for fish farm and waste management practices.
format Dataset
author Erin F. Hamilton
Geraint Element
Peter van Coeverden de Groot
Katja Engel
Josh D. Neufeld
Vishal Shah
Virginia K. Walker
author_facet Erin F. Hamilton
Geraint Element
Peter van Coeverden de Groot
Katja Engel
Josh D. Neufeld
Vishal Shah
Virginia K. Walker
author_sort Erin F. Hamilton
title Table_5_Anadromous Arctic Char Microbiomes: Bioprospecting in the High Arctic.pdf
title_short Table_5_Anadromous Arctic Char Microbiomes: Bioprospecting in the High Arctic.pdf
title_full Table_5_Anadromous Arctic Char Microbiomes: Bioprospecting in the High Arctic.pdf
title_fullStr Table_5_Anadromous Arctic Char Microbiomes: Bioprospecting in the High Arctic.pdf
title_full_unstemmed Table_5_Anadromous Arctic Char Microbiomes: Bioprospecting in the High Arctic.pdf
title_sort table_5_anadromous arctic char microbiomes: bioprospecting in the high arctic.pdf
publishDate 2019
url https://doi.org/10.3389/fbioe.2019.00032.s006
https://figshare.com/articles/Table_5_Anadromous_Arctic_Char_Microbiomes_Bioprospecting_in_the_High_Arctic_pdf/7768892
geographic Arctic
Arctic Ocean
geographic_facet Arctic
Arctic Ocean
genre Arctic
Arctic Ocean
inuit
Salvelinus alpinus
genre_facet Arctic
Arctic Ocean
inuit
Salvelinus alpinus
op_relation doi:10.3389/fbioe.2019.00032.s006
https://figshare.com/articles/Table_5_Anadromous_Arctic_Char_Microbiomes_Bioprospecting_in_the_High_Arctic_pdf/7768892
op_rights CC BY 4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.3389/fbioe.2019.00032.s006
_version_ 1766319763546439680

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