Antarctic Bioconstructional Bryozoans from Terra Nova Bay (Ross Sea): Morphology, Skeletal Structures and Biomineralization

Among Antarctic bryozoans, some species are able to develop calcitic bioconstructions promoting habitat complexity, but the processes leading to biomineral formation are mostly unknown. The present work investigated three Antarctic bryozoans, from morphological to skeletal features, including the or...

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Published in:Minerals
Main Authors: Chiara Lombardi, Piotr Kuklinski, Edoardo Spirandelli, Giorgio Bruzzone, Giancarlo Raiteri, Andrea Bordone, Claudio Mazzoli, Matthias López Correa, Robert van Geldern, Laurent Plasseraud, Jérôme Thomas, Frédéric Marin
Format: Text
Language:English
Published: Multidisciplinary Digital Publishing Institute 2023
Subjects:
Bryozoa
Antarctica
calcifying ecosystem
growth check lines
zooid morphometrics
skeletal organic matrix (SOM)
seawater stable isotopes
climate change
Antarctic
Ross Sea
Terra Nova Bay
The Gib
Antarc*
Online Access:https://doi.org/10.3390/min13020246
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record_format openpolar
spelling ftmdpi:oai:mdpi.com:/2075-163X/13/2/246/ 2023-08-20T04:00:25+02:00 Antarctic Bioconstructional Bryozoans from Terra Nova Bay (Ross Sea): Morphology, Skeletal Structures and Biomineralization Chiara Lombardi Piotr Kuklinski Edoardo Spirandelli Giorgio Bruzzone Giancarlo Raiteri Andrea Bordone Claudio Mazzoli Matthias López Correa Robert van Geldern Laurent Plasseraud Jérôme Thomas Frédéric Marin agris 2023-02-09 application/pdf https://doi.org/10.3390/min13020246 EN eng Multidisciplinary Digital Publishing Institute Biomineralization and Biominerals https://dx.doi.org/10.3390/min13020246 https://creativecommons.org/licenses/by/4.0/ Minerals; Volume 13; Issue 2; Pages: 246 Bryozoa Antarctica calcifying ecosystem growth check lines zooid morphometrics skeletal organic matrix (SOM) seawater stable isotopes climate change Text 2023 ftmdpi https://doi.org/10.3390/min13020246 2023-08-01T08:43:43Z Among Antarctic bryozoans, some species are able to develop calcitic bioconstructions promoting habitat complexity, but the processes leading to biomineral formation are mostly unknown. The present work investigated three Antarctic bryozoans, from morphological to skeletal features, including the organic matrix associated with the skeleton (SOM). Cellarinella nutti Rogick, 1956 and Reteporella frigida Waters, 1904 were collected in November 2018 from a shallow site (25 m) and Cellarinella njegovanae Rogick, 1956 from a deep site (110 m) at Terra Nova Bay (Ross Sea, Antarctica). Both Cellarinella species showed 5–6 “growth check lines” (gcl) on their laminae. The morphometrical characterization conducted on the growth bands (gb) and zooids, within the band across bands, revealed a variability in length with time (C. nutti: from 4099 µm for gb1 to 1449 µm for gb6; C. njegovanae: from 1974 µm for gb 3 to 7127 µm for gb2). Zooid length varied within gb, from the proximal to the distal part of the bands, but differences also occurred across bands. The shortest zooids (~625 µm) were found at the proximal part and the longest (~ 1190 µm) in the middle part of the gb in C. nutti, whereas in C. njegovanae the shortest zooids (~ 660 µm) were found in the distal part and the longest (~1190 µm) in the proximal part of the gb. Micro-CT analyses indicated the ratio of basal zooidal walls (RbwT gcl/gb) ranged from 3.0 to 4.9 in C. nutti and from 2.3 to 5.9 in C. njegovanae, whereas Reteporella frigida did not form any gcl on either side of the colony. Preliminary characterizations of the SOM for the three species evidenced a mixture of proteins and polysaccharides with properties similar to those of better-known biominerals, in terms of quantity and electrophoretic behavior. In addition, a “lectin fingerprint” has been established for the first time in bryozoans, displaying the presence of chitin or chitin-related saccharides. Understanding the complexity of the processes regulating skeleton formation is a key aspect in ... Text Antarc* Antarctic Antarctica Ross Sea MDPI Open Access Publishing Antarctic Ross Sea Terra Nova Bay The Gib ENVELOPE(-57.531,-57.531,51.817,51.817) Minerals 13 2 246
institution Open Polar
collection MDPI Open Access Publishing
op_collection_id ftmdpi
language English
topic Bryozoa
Antarctica
calcifying ecosystem
growth check lines
zooid morphometrics
skeletal organic matrix (SOM)
seawater stable isotopes
climate change
spellingShingle Bryozoa
Antarctica
calcifying ecosystem
growth check lines
zooid morphometrics
skeletal organic matrix (SOM)
seawater stable isotopes
climate change
Chiara Lombardi
Piotr Kuklinski
Edoardo Spirandelli
Giorgio Bruzzone
Giancarlo Raiteri
Andrea Bordone
Claudio Mazzoli
Matthias López Correa
Robert van Geldern
Laurent Plasseraud
Jérôme Thomas
Frédéric Marin
Antarctic Bioconstructional Bryozoans from Terra Nova Bay (Ross Sea): Morphology, Skeletal Structures and Biomineralization
topic_facet Bryozoa
Antarctica
calcifying ecosystem
growth check lines
zooid morphometrics
skeletal organic matrix (SOM)
seawater stable isotopes
climate change
description Among Antarctic bryozoans, some species are able to develop calcitic bioconstructions promoting habitat complexity, but the processes leading to biomineral formation are mostly unknown. The present work investigated three Antarctic bryozoans, from morphological to skeletal features, including the organic matrix associated with the skeleton (SOM). Cellarinella nutti Rogick, 1956 and Reteporella frigida Waters, 1904 were collected in November 2018 from a shallow site (25 m) and Cellarinella njegovanae Rogick, 1956 from a deep site (110 m) at Terra Nova Bay (Ross Sea, Antarctica). Both Cellarinella species showed 5–6 “growth check lines” (gcl) on their laminae. The morphometrical characterization conducted on the growth bands (gb) and zooids, within the band across bands, revealed a variability in length with time (C. nutti: from 4099 µm for gb1 to 1449 µm for gb6; C. njegovanae: from 1974 µm for gb 3 to 7127 µm for gb2). Zooid length varied within gb, from the proximal to the distal part of the bands, but differences also occurred across bands. The shortest zooids (~625 µm) were found at the proximal part and the longest (~ 1190 µm) in the middle part of the gb in C. nutti, whereas in C. njegovanae the shortest zooids (~ 660 µm) were found in the distal part and the longest (~1190 µm) in the proximal part of the gb. Micro-CT analyses indicated the ratio of basal zooidal walls (RbwT gcl/gb) ranged from 3.0 to 4.9 in C. nutti and from 2.3 to 5.9 in C. njegovanae, whereas Reteporella frigida did not form any gcl on either side of the colony. Preliminary characterizations of the SOM for the three species evidenced a mixture of proteins and polysaccharides with properties similar to those of better-known biominerals, in terms of quantity and electrophoretic behavior. In addition, a “lectin fingerprint” has been established for the first time in bryozoans, displaying the presence of chitin or chitin-related saccharides. Understanding the complexity of the processes regulating skeleton formation is a key aspect in ...
format Text
author Chiara Lombardi
Piotr Kuklinski
Edoardo Spirandelli
Giorgio Bruzzone
Giancarlo Raiteri
Andrea Bordone
Claudio Mazzoli
Matthias López Correa
Robert van Geldern
Laurent Plasseraud
Jérôme Thomas
Frédéric Marin
author_facet Chiara Lombardi
Piotr Kuklinski
Edoardo Spirandelli
Giorgio Bruzzone
Giancarlo Raiteri
Andrea Bordone
Claudio Mazzoli
Matthias López Correa
Robert van Geldern
Laurent Plasseraud
Jérôme Thomas
Frédéric Marin
author_sort Chiara Lombardi
title Antarctic Bioconstructional Bryozoans from Terra Nova Bay (Ross Sea): Morphology, Skeletal Structures and Biomineralization
title_short Antarctic Bioconstructional Bryozoans from Terra Nova Bay (Ross Sea): Morphology, Skeletal Structures and Biomineralization
title_full Antarctic Bioconstructional Bryozoans from Terra Nova Bay (Ross Sea): Morphology, Skeletal Structures and Biomineralization
title_fullStr Antarctic Bioconstructional Bryozoans from Terra Nova Bay (Ross Sea): Morphology, Skeletal Structures and Biomineralization
title_full_unstemmed Antarctic Bioconstructional Bryozoans from Terra Nova Bay (Ross Sea): Morphology, Skeletal Structures and Biomineralization
title_sort antarctic bioconstructional bryozoans from terra nova bay (ross sea): morphology, skeletal structures and biomineralization
publisher Multidisciplinary Digital Publishing Institute
publishDate 2023
url https://doi.org/10.3390/min13020246
op_coverage agris
long_lat ENVELOPE(-57.531,-57.531,51.817,51.817)
geographic Antarctic
Ross Sea
Terra Nova Bay
The Gib
geographic_facet Antarctic
Ross Sea
Terra Nova Bay
The Gib
genre Antarc*
Antarctic
Antarctica
Ross Sea
genre_facet Antarc*
Antarctic
Antarctica
Ross Sea
op_source Minerals; Volume 13; Issue 2; Pages: 246
op_relation Biomineralization and Biominerals
https://dx.doi.org/10.3390/min13020246
op_rights https://creativecommons.org/licenses/by/4.0/
op_doi https://doi.org/10.3390/min13020246
container_title Minerals
container_volume 13
container_issue 2
container_start_page 246
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