Properties, morphogenesis, and effect of acidification on spines of the cidaroid sea urchin Phyllacanthus imperialis

Dery, A.; Guibourt, V.; Catarino, A. I.; Compère, Philippe; Dubois, Philippe

doi:10.1111/ivb.12054

Request a copy

Article (Scientific journals)

Properties, morphogenesis, and effect of acidification on spines of the cidaroid sea urchin Phyllacanthus imperialis

Dery, A.; Guibourt, V.; Catarino, A. I. et al.

2014 • In Invertebrate Biology, 133 (2), p. 188-199

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/183620

DOI
10.1111/ivb.12054

Files (1)Send to Details Statistics Bibliography Similar publications

Files

Full Text

Dery_et_al-2014-Invertebrate_Biology.pdf

Publisher postprint (4.45 MB)

Request a copy

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Keywords :

Echinoderm; Global change; Skeleton; Solubility

Abstract :

[en] Cidaroid sea urchins are the sister clade to all other extant echinoids and have numerous unique features, including unusual primary spines. These lack an epidermis when mature, exposing their high-magnesium calcite skeleton to seawater and allowing the settlement of numerous epibionts. Cidaroid spines are made of an inner core of classical monocrystalline skeleton and an outer layer of polycrystalline magnesium calcite. Interestingly, cidaroids survived the Permian-Triassic crisis, which was characterized by severe acidification of the ocean. Currently, numerous members of this group inhabit the deep ocean, below the saturation horizon for their magnesium calcite skeleton. This suggests that members of this taxon may have characteristics that may allow them to resist ongoing ocean acidification linked to global change. We compared the effect of acidified seawater (pH 7.2, 7.6, or 8.2) on mature spines with a fully developed cortex to that on young, growing spines, in which only the stereom core was developed. The cortex of mature spines was much more resistant to etching than the stereom of young spines. We then examined the properties of the cortex that might be responsible for its resistance compared to the underlying stereomic layers, namely morphology, intramineral organic material, magnesium concentration, intrinsic solubility of the mineral, and density. Our results indicate that the acidification resistance of the cortex is probably due to its lower magnesium concentration and higher density, the latter reducing the amount of surface area in contact with acidified seawater. The biofilm and epibionts covering the cortex of mature spines may also reduce its exposure to seawater. © 2014, The American Microscopical Society, Inc.

Disciplines :

Aquatic sciences & oceanology

Author, co-author :

Dery, A.; Laboratoire de Biologie Marine, Université Libre de Bruxelles, Brussels, B-1050, Belgium

Guibourt, V.; Laboratoire de Biologie Marine, Université Libre de Bruxelles, Brussels, B-1050, Belgium

Catarino, A. I.; Laboratoire de Biologie Marine, Université Libre de Bruxelles, Brussels, B-1050, Belgium

Compère, Philippe ; Université de Liège > Département de Biologie, Ecologie et Evolution > Département de Biologie, Ecologie et Evolution

Dubois, Philippe; Université Libre de Bruxelles - ULB > Laboratoire de Biologie Marine

Language :

English

Title :

Properties, morphogenesis, and effect of acidification on spines of the cidaroid sea urchin Phyllacanthus imperialis

Publication date :

2014

Journal title :

Invertebrate Biology

ISSN :

1077-8306

Publisher :

Blackwell Publishing Inc.

Volume :

133

Issue :

Pages :

188-199

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 03 July 2015

Statistics

Number of views

55 (6 by ULiège)

Number of downloads

1 (0 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

OpenAlex citations

Bibliography

Ameye L, De Becker G, Killian C, Wilt F, Kemps R, Kuypers S, & Dubois P 2001. Proteins and saccharides of the sea urchin organic matrix of mineralization: characterization and localization in the spine skeleton. J. Struct. Biol. 134: 56-66.
Andersson AJ, Mackenzie FT, & Bates NR 2008. Life on the margin: implications of ocean acidification on Mg-calcite, high latitude and cold-water marine calcifiers. Mar. Ecol. Prog. Ser. 373: 265-273.
Borig P 1933. Über wachstum und regeneration der stacheln einiger seeigle. Z. Morph. Ökol. Tiere 27: 624-653.
Byrne M 2011. Unshelled abalone and corrupted urchins: development of marine calcifiers in a changing ocean. Proc. R. Soc. Lond., Ser. B: Biol. Sci. 278: 2376-2383.
Catarino AI, Guibourt V, Moureaux C, De Ridder C, Compère P, & Dubois P 2013. Antarctic Ctenocidaris speciosa spines: lessons from the deep. Cah. Biol. Mar. 54: 649-655.
Cutress BM 1965. Observations on growth in Eucidaris tribuloides (Lamarck), with special reference to the origin of the oral primary spines. Bull. Mar. Sci. 5: 797-834.
David B, Choné T, Mooi R, & De Ridder C 2005. Antarctic Echinoidea. Synopses of the Antarctic Benthos, Vol. 10. Koeltz Scientific Books, Königstein. 274 pp.
David B, Stock S, De Carlo F, Hétérier V, & De Ridder C 2009. Microstructures of Antarctic cidaroid spines: diversity of shapes and ectosymbiont attachments. Mar. Biol. 156: 1559-1572.
Del Valls TA & Dickson AG 1998. The pH of buffers based on 2-amino-2- hydroxymethyl-1, 3-propanediol ("TRIS") in synthetic sea water. Deep-Sea Res. 1: 1541-1554.
Doncaster CP & Davey AJ 2007. Analysis of Variance and Covariance. Cambridge University Press, UK. 288 pp.
Dubois P 1991. Morphological evidence of coherent organic material within the stereom of postmetamorphic echinoderms. In: Mechanisms and Phylogeny of Mineralization in Biological Systems. Suga S & Nakahara H, eds., pp. 41-45. Springer-Verlag, Tokyo.
Dubois P & Chen C 1989. Calcification in Echinoderms. In: Echinoderm Studies, Vol. 3. Jangoux M & Lawrence JM, eds., pp. 109-178. Balkema, Amsterdam.
Duckworth AR & Peterson BJ 2013. Effects of seawater temperature and pH on the boring rates of the sponge Cliona celata in scallop shells. Mar. Biol. 160, 27-35. doi:10.1007/s00227-012-2053-z.
Dupont S, Dorey N, & Thorndyke M 2010. What meta-analysis can tell us about vulnerability of marine biodiversity to ocean acidification? Estuar. Coast. Shelf Sci. 89: 182-185.
Feely RA, Sabine CL, Lee K, Berelson W, Kleypas J, Fabry VJ, & Millero FJ 2004. Impact of anthropogenic CO2 on the CaCO3 system in the oceans. Science 305: 362-366.
Feely RA, Doney SC, & Cooley SR 2009. Ocean acidification. Present conditions and future changes in a high-CO2 world. Oceanography 22: 36-47.
Gran G 1952. Determination of the equivalence point in potentiometric titrages-Part II. Analyst 77: 661-671.
Grossmann JN & Nebelsick JH 2013. Comparative morphological and structural analysis of selected cidaroid and camarodont sea urchin spines. Zoomorphology 132: 301-315.
Harper EM 2000. Are calcitic layers an effective adaptation against shell dissolution in the Bivalvia? J. Zool. 251: 179-186.
Heatfield BM 1971. Growth of the calcareous skeleton during regeneration of spines of the sea urchin, Strongylocentrotus purpuratus (Stimpson): a light and scanning electron microscopic study. J. Morphol. 134: 57-90.
Hétérier V, De Ridder C, David B, & Rigaud T 2004. Comparative biodiversity of ectosymbionts in two Antarctic cidarid echinoids, Ctenocidaris spinosa and Rhynchocidaris triplopora. In: Echinoderms München. Heinzeller T & Nebelsick JH, eds., pp. 201-205. Taylor & Francis, London.
Hofmann GE & Todgham AE 2010. Living in the now: physiological mechanisms to tolerate a rapidly changing environment. Annu. Rev. Physiol. 72: 127-145.
Kroh A & Smith AB 2010. The phylogeny and classification of post-Palaeozoic echinoids. J. Syst. Palaeontol. 8: 147-212.
Märkel K & Röser U 1983a. The spine tissues in the echinoid Eucidaris tribuloides. Zoomorphology 103: 25-41.
Märkel K & Röser U 1983b. Calcite resorption in the spine of the echinoid Eucidaris tribuloides. Zoomorphology 103: 43-58.
Märkel K, Kubanek F, & Willgallis A 1971. Polykristalliner Calcit bei Seeigeln (Echinodermata, Echinoidea). Z. Zellforsch 119: 355-377.
Melzner F, Gutowska MA, Langenbuch M, Dupont S, Lucassen M, Thorndyke MC, Bleich M & Pörtner H-O 2009. Physiological basis for high CO2 tolerance in marine ectothermic animals: pre-adaptation through lifestyle and ontogeny? Biogeosciences 6: 2313-2331.
Millero FJ 2001. Physical Chemistry of Natural Waters. Wiley-Interscience, New-York. 654 pp.
Mischor B 1975. Zur Morphologie und Regeneration der Hohlstacheln von Diadema antillarium Philippi und Echinothrix diadema (L.) (Echinoidea, Diadematidae). Zoomorphology 82: 243-258.
Morse JW & Mackenzie FT 1990. Geochemistry of Sedimentary Carbonates. Elsevier Science Publishers B.V, Amsterdam. 707 pp.
Morse JW, Andersson AJ, & Mackenzie FT 2006. Initial responses of carbonate-rich shelf sediments to rising atmospheric pCO2 and "ocean acidification": role of high Mg-calcites. Geochim. Cosmochim. Acta 70: 5814-5830.
Mortensen Th 1928. A monograph of the Echinoidea; I. Cidaroidea, 1- 551. c.A. Reitzel, Kebenhavn; H. Milford, Oxford University Press, London.
Moureaux C, Pérez-Huerta A, Compère P, Zhu W, Leloup T, Cusack M, & Dubois P 2010. Structure, composition and mechanical relations to function in sea urchin spine. J. Struct. Biol. 170: 41-49.
Orr JC, Fabry VJ, Aumont O, Bopp L, Doney SC, Feely RA, Gnanadesikan A, Gruber N, Ishida A, Joos F, Key RM, Lindsay K, Maier-Reimer E, Matear R, Monfray P, Mouchet A, Najjar RG, Plattner G-K, Rodgers KB, Sabine CL, Sarmiento JL, Schlitzer R, Slater RD, Totterdell IJ, Weirig M-F, Yamanaka Y, & Yool A 2005. Anthropogenic ocean acidification over the twenty-first century and its impact on calcifying organisms. Nature 437: 681-686.
Pelejero C, Calvo E, & Hoegh-Guldberg O 2010. Paleo-perspectives on ocean acidification. Trends Ecol. Evol. 35: 332-344.
Pierrot D, Lewis E, & Wallace DWR 2006. MS Excel Program Developed for CO2 System Calculations. ORNL/CDIAC-105a. Carbon dioxide Information Analysis Center, Oak Ridge National Laboratory, U.S. Department of Energy, Oak Ridge, Tennessee.
Plummer LN & Mackenzie FT 1974. Predicting mineral solubility from rate data: application to the dissolution of Mg- calcites. Am. J. Sci. 274: 61-83.
Politi Y, Arad T, Klein E, Weiner S, & Addadi L 2004. Sea urchin spine calcite forms via a transient amorphous calcium carbonate phase. Science 306: 1161-1164.
Pörtner H 2008. Ecosystem effects of ocean acidification in times of ocean warming: a physiologist's view. Mar. Ecol. Prog. Ser. 373: 203-217.
Pörtner H, Langenbuch M, & Reipschläger A 2004. Biological impact of elevated ocean CO2 concentrations: lessons from animal physiology and earth history. Oceanography 60: 705-718.
Prouho H 1887. Recherches sur le Dorocidaris papillata et quelques autres échinides de la Méditerranée. Arch. Zool. Exp. 5: 214-380.
Schöne BR, Dunca E, Fiebig J, & Pfeiffer M 2005. Mutvei's solution: an ideal agent for resolving microgrowth structures of biogenic carbonates. Palaeogeogr., Palaeoclimatol. Palaeoecology 228: 149-166.
Smith A 1980. Stereome microstructure of the Echinoid test. Spec. Pap. Palaeontol. 25: 1-81.
Stumpp M, Trübenbach K, Brennecke D, Hu MY, & Melzner F 2012. Resource allocation and extracellular acid-base status in the sea urchin Strongylocentrotus droebachiensis in response to CO2 induced seawater acidification. Aquat. Toxicol. 110-111: 194-207.
Thomsen J, Gutowska MA, Saphörster J, Heinemann A, Trübenbach K, Fietzke J, Hiebenthal C, Eisenhauer A, Körtzinger A, Whal M, & Melzner F 2010. Calcifying invertebrates succeed in a naturally CO2-rich coastal habitat but are threatened by high levels of future acidification. Biogeosciences 7: 3879-3891.
Tunnicliffe V, Davies KTA, Butterfield DA, Embley RW, Rose JM, & Chadwick WW 2009. Survival of mussels in extremely acidic waters on a submarine volcano. Nature Geosci. 2: 344-348.
Twitchett RJ & Oji T 2005. Early Triassic recovery of echinoderms. C. R. Palevol. 4: 531-542.
Walter LM & Morse JW 1984. Magnesian calcite stabilities: a reevaluation. Geochim. Cosmochim. Acta 48: 1059-1069.
Wisshak M, Schönberg CHL, Form A, & Freiwald A 2012. Ocean acidification accelerates reef bioerosion. PLoS ONE 7(9): e45124. doi:10.1371/journal.pone.0045124.
Zeebe RE 2012. History of seawater carbonate chemistry, atmospheric CO2, and ocean acidification. Annu. Rev. Earth Planet. Sci. 40: 141-165.