Oceanographic structure drives the assembly processes of microbial eukaryotic communities

Abstract Arctic Ocean microbial eukaryote phytoplankton form subsurface chlorophyll maximum (SCM), where much of the annual summer production occurs. This SCM is particularly persistent in the Western Arctic Ocean, which is strongly salinity stratified. The recent loss of multiyear sea ice and incre...

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Published in:	The ISME Journal
Main Authors:	Monier, Adam, Comte, Jérôme, Babin, Marcel, Forest, Alexandre, Matsuoka, Atsushi, Lovejoy, Connie
Format:	Article in Journal/Newspaper
Language:	English
Published:	Oxford University Press (OUP) 2014
Subjects:	Arctic Arctic Ocean Mackenzie River Pacific Mackenzie river Phytoplankton Sea ice
Online Access:	http://dx.doi.org/10.1038/ismej.2014.197 http://www.nature.com/articles/ismej2014197.pdf http://www.nature.com/articles/ismej2014197 https://academic.oup.com/ismej/article-pdf/9/4/990/56108502/41396_2015_article_bfismej2014197.pdf

id	croxfordunivpr:10.1038/ismej.2014.197
record_format	openpolar
spelling	croxfordunivpr:10.1038/ismej.2014.197 2024-10-13T14:04:57+00:00 Oceanographic structure drives the assembly processes of microbial eukaryotic communities Monier, Adam Comte, Jérôme Babin, Marcel Forest, Alexandre Matsuoka, Atsushi Lovejoy, Connie 2014 http://dx.doi.org/10.1038/ismej.2014.197 http://www.nature.com/articles/ismej2014197.pdf http://www.nature.com/articles/ismej2014197 https://academic.oup.com/ismej/article-pdf/9/4/990/56108502/41396_2015_article_bfismej2014197.pdf en eng Oxford University Press (OUP) https://creativecommons.org/licenses/by-nc-nd/3.0/ https://creativecommons.org/licenses/by-nc-nd/3.0/ The ISME Journal volume 9, issue 4, page 990-1002 ISSN 1751-7362 1751-7370 journal-article 2014 croxfordunivpr https://doi.org/10.1038/ismej.2014.197 2024-09-17T04:31:38Z Abstract Arctic Ocean microbial eukaryote phytoplankton form subsurface chlorophyll maximum (SCM), where much of the annual summer production occurs. This SCM is particularly persistent in the Western Arctic Ocean, which is strongly salinity stratified. The recent loss of multiyear sea ice and increased particulate-rich river discharge in the Arctic Ocean results in a greater volume of fresher water that may displace nutrient-rich saltier waters to deeper depths and decrease light penetration in areas affected by river discharge. Here, we surveyed microbial eukaryotic assemblages in the surface waters, and within and below the SCM. In most samples, we detected the pronounced SCM that usually occurs at the interface of the upper mixed layer and Pacific Summer Water (PSW). Poorly developed SCM was seen under two conditions, one above PSW and associated with a downwelling eddy, and the second in a region influenced by the Mackenzie River plume. Four phylogenetically distinct communities were identified: surface, pronounced SCM, weak SCM and a deeper community just below the SCM. Distance–decay relationships and phylogenetic structure suggested distinct ecological processes operating within these communities. In the pronounced SCM, picophytoplanktons were prevalent and community assembly was attributed to water mass history. In contrast, environmental filtering impacted the composition of the weak SCM communities, where heterotrophic Picozoa were more numerous. These results imply that displacement of Pacific waters to greater depth and increased terrigenous input may act as a control on SCM development and result in lower net summer primary production with a more heterotroph dominated eukaryotic microbial community. Article in Journal/Newspaper Arctic Arctic Ocean Mackenzie river Phytoplankton Sea ice Oxford University Press Arctic Arctic Ocean Mackenzie River Pacific The ISME Journal 9 4 990 1002
institution	Open Polar
collection	Oxford University Press
op_collection_id	croxfordunivpr
language	English
description	Abstract Arctic Ocean microbial eukaryote phytoplankton form subsurface chlorophyll maximum (SCM), where much of the annual summer production occurs. This SCM is particularly persistent in the Western Arctic Ocean, which is strongly salinity stratified. The recent loss of multiyear sea ice and increased particulate-rich river discharge in the Arctic Ocean results in a greater volume of fresher water that may displace nutrient-rich saltier waters to deeper depths and decrease light penetration in areas affected by river discharge. Here, we surveyed microbial eukaryotic assemblages in the surface waters, and within and below the SCM. In most samples, we detected the pronounced SCM that usually occurs at the interface of the upper mixed layer and Pacific Summer Water (PSW). Poorly developed SCM was seen under two conditions, one above PSW and associated with a downwelling eddy, and the second in a region influenced by the Mackenzie River plume. Four phylogenetically distinct communities were identified: surface, pronounced SCM, weak SCM and a deeper community just below the SCM. Distance–decay relationships and phylogenetic structure suggested distinct ecological processes operating within these communities. In the pronounced SCM, picophytoplanktons were prevalent and community assembly was attributed to water mass history. In contrast, environmental filtering impacted the composition of the weak SCM communities, where heterotrophic Picozoa were more numerous. These results imply that displacement of Pacific waters to greater depth and increased terrigenous input may act as a control on SCM development and result in lower net summer primary production with a more heterotroph dominated eukaryotic microbial community.
format	Article in Journal/Newspaper
author	Monier, Adam Comte, Jérôme Babin, Marcel Forest, Alexandre Matsuoka, Atsushi Lovejoy, Connie
spellingShingle	Monier, Adam Comte, Jérôme Babin, Marcel Forest, Alexandre Matsuoka, Atsushi Lovejoy, Connie Oceanographic structure drives the assembly processes of microbial eukaryotic communities
author_facet	Monier, Adam Comte, Jérôme Babin, Marcel Forest, Alexandre Matsuoka, Atsushi Lovejoy, Connie
author_sort	Monier, Adam
title	Oceanographic structure drives the assembly processes of microbial eukaryotic communities
title_short	Oceanographic structure drives the assembly processes of microbial eukaryotic communities
title_full	Oceanographic structure drives the assembly processes of microbial eukaryotic communities
title_fullStr	Oceanographic structure drives the assembly processes of microbial eukaryotic communities
title_full_unstemmed	Oceanographic structure drives the assembly processes of microbial eukaryotic communities
title_sort	oceanographic structure drives the assembly processes of microbial eukaryotic communities
publisher	Oxford University Press (OUP)
publishDate	2014
url	http://dx.doi.org/10.1038/ismej.2014.197 http://www.nature.com/articles/ismej2014197.pdf http://www.nature.com/articles/ismej2014197 https://academic.oup.com/ismej/article-pdf/9/4/990/56108502/41396_2015_article_bfismej2014197.pdf
geographic	Arctic Arctic Ocean Mackenzie River Pacific
geographic_facet	Arctic Arctic Ocean Mackenzie River Pacific
genre	Arctic Arctic Ocean Mackenzie river Phytoplankton Sea ice
genre_facet	Arctic Arctic Ocean Mackenzie river Phytoplankton Sea ice
op_source	The ISME Journal volume 9, issue 4, page 990-1002 ISSN 1751-7362 1751-7370
op_rights	https://creativecommons.org/licenses/by-nc-nd/3.0/ https://creativecommons.org/licenses/by-nc-nd/3.0/
op_doi	https://doi.org/10.1038/ismej.2014.197
container_title	The ISME Journal
container_volume	9
container_issue	4
container_start_page	990
op_container_end_page	1002
_version_	1812810770002477056

Oceanographic structure drives the assembly processes of microbial eukaryotic communities

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