Phytoplankton community structure and stocks in the Southern Ocean (30-80E) determined by CHEMTAX analysis of HPLC pigment signatures

The geographic distribution, stocks and vertical profiles of phytoplankton of the seasonal ice zone off east Antarctica were determined during the 20052006 austral summer during the Baseline Research on Oceanography, Krill and the Environment-West (BROKE-West) survey. CHEMTAX analysis of HPLC pigmen...

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Published in:Deep Sea Research Part II: Topical Studies in Oceanography
Main Authors: Wright, SW, van den Enden, R, Pearce, I, Davidson, A, Scott, FJ, Westwood, KJ
Format: Article in Journal/Newspaper
Language:English
Published: Pergamon-Elsevier Science Ltd 2010
Subjects:
Biological Sciences
Other Biological Sciences
Global Change Biology
Antarctic
Austral
East Antarctica
Southern Ocean
The Antarctic
Weddell
Antarc*
Antarctica
Sea ice
Online Access:https://doi.org/10.1016/j.dsr2.2009.06.015
http://ecite.utas.edu.au/79886
id ftunivtasecite:oai:ecite.utas.edu.au:79886
record_format openpolar
institution Open Polar
collection eCite UTAS (University of Tasmania)
op_collection_id ftunivtasecite
language English
topic Biological Sciences
Other Biological Sciences
Global Change Biology
spellingShingle Biological Sciences
Other Biological Sciences
Global Change Biology
Wright, SW
van den Enden, R
Pearce, I
Davidson, A
Scott, FJ
Westwood, KJ
Phytoplankton community structure and stocks in the Southern Ocean (30-80E) determined by CHEMTAX analysis of HPLC pigment signatures
topic_facet Biological Sciences
Other Biological Sciences
Global Change Biology
description The geographic distribution, stocks and vertical profiles of phytoplankton of the seasonal ice zone off east Antarctica were determined during the 20052006 austral summer during the Baseline Research on Oceanography, Krill and the Environment-West (BROKE-West) survey. CHEMTAX analysis of HPLC pigment samples, coupled with microscopy, permitted a detailed survey along seven transects covering an extensive area between 30E and 80E, from 62S to the coast. Significant differences were found in the composition and stocks of populations separated by the Southern Boundary of the Antarctic Circumpolar Current (SB), as well as a small influence of the Weddell Gyre in the western sector of the zone south of the Antarctic Circumpolar Current (SACCZ). Within the SACCZ, we identified a primary bloom under the ice, a secondary bloom near the ice edge, and an open-ocean deep population. The similarity of distribution patterns across all transects allowed us to generalise a hypothesized sequence for the season. The primary phytoplankton bloom, with stocks of Chl a up to 239 mg m−2, occurred about 35 days before complete disappearance of the sea ice, and contained both cells from the water column and those released from melting ice. These blooms were composed of haptophytes (in particular, colonies and gametes of Phaeocystis antarctica), diatoms and cryptophytes (or the cryptophyte symbiont-containing ciliate Myrionecta rubrum). Aggregates released by melting ice quickly sank from the upper water column and Chl a stocks declined to 5692 mg m−2, but the bloom of diatoms and, to a lesser extent, cryptophytes continued until about 20 days after ice melt. The disappearance of sea ice coincided with a sharp increase in P. antarctica and grazing, as indicated by increasing phaeophytin a and phaeophorbide a. Chlorophyllide content suggests that the diatom bloom then senesced, probably due to iron exhaustion. Stocks rapidly declined, apparently due to grazing krill that moved southward following the retreating sea ice. We suggest that grazing of the bloom and export of faecal pellets stripped the upper water column of iron (as suggested by low Fv/Fm ratios and CHEMTAX pigment ratios in Haptophytes iron was not measured). Thus, export of iron by grazing, and possibly sedimentation, created a southward migrating iron gradient, limiting growth in the upper water column. North of the postulated iron gradient, a nanoflagellate community developed at depth, with Chl a stocks from 3649 mg m−2. This community was probably based on regenerated production, sustained by residual and/or upwelling iron, as indicated by a close correspondence between distributions of Chl a and profiles of Fv/Fm. The community consisted of haptophytes (chiefly Phaeocystis gametes), dinoflagellates, prasinophytes, cryptophytes, and some small diatoms. Selective grazing by krill may have fashioned and maintained the community. North of the SB, Chl a ranged from 4067 mg m−2 and was found predominantly in the mixed layer, but Fv/Fm ratios remained low, suggesting the community of P. antarctica and diatoms was iron-limited. These interpretations provide a cogent explanation for the composition and structure of late summer microbial populations in the marginal ice zone.
format Article in Journal/Newspaper
author Wright, SW
van den Enden, R
Pearce, I
Davidson, A
Scott, FJ
Westwood, KJ
author_facet Wright, SW
van den Enden, R
Pearce, I
Davidson, A
Scott, FJ
Westwood, KJ
author_sort Wright, SW
title Phytoplankton community structure and stocks in the Southern Ocean (30-80E) determined by CHEMTAX analysis of HPLC pigment signatures
title_short Phytoplankton community structure and stocks in the Southern Ocean (30-80E) determined by CHEMTAX analysis of HPLC pigment signatures
title_full Phytoplankton community structure and stocks in the Southern Ocean (30-80E) determined by CHEMTAX analysis of HPLC pigment signatures
title_fullStr Phytoplankton community structure and stocks in the Southern Ocean (30-80E) determined by CHEMTAX analysis of HPLC pigment signatures
title_full_unstemmed Phytoplankton community structure and stocks in the Southern Ocean (30-80E) determined by CHEMTAX analysis of HPLC pigment signatures
title_sort phytoplankton community structure and stocks in the southern ocean (30-80e) determined by chemtax analysis of hplc pigment signatures
publisher Pergamon-Elsevier Science Ltd
publishDate 2010
url https://doi.org/10.1016/j.dsr2.2009.06.015
http://ecite.utas.edu.au/79886
geographic Antarctic
Austral
East Antarctica
Southern Ocean
The Antarctic
Weddell
geographic_facet Antarctic
Austral
East Antarctica
Southern Ocean
The Antarctic
Weddell
genre Antarc*
Antarctic
Antarctica
East Antarctica
Sea ice
Southern Ocean
genre_facet Antarc*
Antarctic
Antarctica
East Antarctica
Sea ice
Southern Ocean
op_relation http://dx.doi.org/10.1016/j.dsr2.2009.06.015
Wright, SW and van den Enden, R and Pearce, I and Davidson, A and Scott, FJ and Westwood, KJ, Phytoplankton community structure and stocks in the Southern Ocean (30-80E) determined by CHEMTAX analysis of HPLC pigment signatures, Deep-Sea Research. Part 2: Topical Studies in Oceanography, 57, (9-10) pp. 758-778. ISSN 0967-0645 (2010) [Refereed Article]
http://ecite.utas.edu.au/79886
op_doi https://doi.org/10.1016/j.dsr2.2009.06.015
container_title Deep Sea Research Part II: Topical Studies in Oceanography
container_volume 57
container_issue 9-10
container_start_page 758
op_container_end_page 778
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spelling ftunivtasecite:oai:ecite.utas.edu.au:79886 2023-05-15T14:02:30+02:00 Phytoplankton community structure and stocks in the Southern Ocean (30-80E) determined by CHEMTAX analysis of HPLC pigment signatures Wright, SW van den Enden, R Pearce, I Davidson, A Scott, FJ Westwood, KJ 2010 https://doi.org/10.1016/j.dsr2.2009.06.015 http://ecite.utas.edu.au/79886 en eng Pergamon-Elsevier Science Ltd http://dx.doi.org/10.1016/j.dsr2.2009.06.015 Wright, SW and van den Enden, R and Pearce, I and Davidson, A and Scott, FJ and Westwood, KJ, Phytoplankton community structure and stocks in the Southern Ocean (30-80E) determined by CHEMTAX analysis of HPLC pigment signatures, Deep-Sea Research. Part 2: Topical Studies in Oceanography, 57, (9-10) pp. 758-778. ISSN 0967-0645 (2010) [Refereed Article] http://ecite.utas.edu.au/79886 Biological Sciences Other Biological Sciences Global Change Biology Refereed Article PeerReviewed 2010 ftunivtasecite https://doi.org/10.1016/j.dsr2.2009.06.015 2019-12-13T21:45:15Z The geographic distribution, stocks and vertical profiles of phytoplankton of the seasonal ice zone off east Antarctica were determined during the 20052006 austral summer during the Baseline Research on Oceanography, Krill and the Environment-West (BROKE-West) survey. CHEMTAX analysis of HPLC pigment samples, coupled with microscopy, permitted a detailed survey along seven transects covering an extensive area between 30E and 80E, from 62S to the coast. Significant differences were found in the composition and stocks of populations separated by the Southern Boundary of the Antarctic Circumpolar Current (SB), as well as a small influence of the Weddell Gyre in the western sector of the zone south of the Antarctic Circumpolar Current (SACCZ). Within the SACCZ, we identified a primary bloom under the ice, a secondary bloom near the ice edge, and an open-ocean deep population. The similarity of distribution patterns across all transects allowed us to generalise a hypothesized sequence for the season. The primary phytoplankton bloom, with stocks of Chl a up to 239 mg m−2, occurred about 35 days before complete disappearance of the sea ice, and contained both cells from the water column and those released from melting ice. These blooms were composed of haptophytes (in particular, colonies and gametes of Phaeocystis antarctica), diatoms and cryptophytes (or the cryptophyte symbiont-containing ciliate Myrionecta rubrum). Aggregates released by melting ice quickly sank from the upper water column and Chl a stocks declined to 5692 mg m−2, but the bloom of diatoms and, to a lesser extent, cryptophytes continued until about 20 days after ice melt. The disappearance of sea ice coincided with a sharp increase in P. antarctica and grazing, as indicated by increasing phaeophytin a and phaeophorbide a. Chlorophyllide content suggests that the diatom bloom then senesced, probably due to iron exhaustion. Stocks rapidly declined, apparently due to grazing krill that moved southward following the retreating sea ice. We suggest that grazing of the bloom and export of faecal pellets stripped the upper water column of iron (as suggested by low Fv/Fm ratios and CHEMTAX pigment ratios in Haptophytes iron was not measured). Thus, export of iron by grazing, and possibly sedimentation, created a southward migrating iron gradient, limiting growth in the upper water column. North of the postulated iron gradient, a nanoflagellate community developed at depth, with Chl a stocks from 3649 mg m−2. This community was probably based on regenerated production, sustained by residual and/or upwelling iron, as indicated by a close correspondence between distributions of Chl a and profiles of Fv/Fm. The community consisted of haptophytes (chiefly Phaeocystis gametes), dinoflagellates, prasinophytes, cryptophytes, and some small diatoms. Selective grazing by krill may have fashioned and maintained the community. North of the SB, Chl a ranged from 4067 mg m−2 and was found predominantly in the mixed layer, but Fv/Fm ratios remained low, suggesting the community of P. antarctica and diatoms was iron-limited. These interpretations provide a cogent explanation for the composition and structure of late summer microbial populations in the marginal ice zone. Article in Journal/Newspaper Antarc* Antarctic Antarctica East Antarctica Sea ice Southern Ocean eCite UTAS (University of Tasmania) Antarctic Austral East Antarctica Southern Ocean The Antarctic Weddell Deep Sea Research Part II: Topical Studies in Oceanography 57 9-10 758 778

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