Direct, carryover, and maternal effects of ocean acidification on snow crab embryos and larvae.

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  • Author(s): Long WC;Long WC; Swiney KM; Swiney KM; Foy RJ; Foy RJ
  • Source:
    PloS one [PLoS One] 2023 Oct 18; Vol. 18 (10), pp. e0276360. Date of Electronic Publication: 2023 Oct 18 (Print Publication: 2023).
  • Publication Type:
    Journal Article
  • Language:
    English
  • Additional Information
    • Source:
      Publisher: Public Library of Science Country of Publication: United States NLM ID: 101285081 Publication Model: eCollection Cited Medium: Internet ISSN: 1932-6203 (Electronic) Linking ISSN: 19326203 NLM ISO Abbreviation: PLoS One Subsets: MEDLINE
    • Publication Information:
      Original Publication: San Francisco, CA : Public Library of Science
    • Subject Terms:
      Seawater*/chemistry ; Brachyura*; Animals ; Female ; Larva ; Hydrogen-Ion Concentration ; Maternal Inheritance ; Ocean Acidification ; Calcium ; Carbon Dioxide/analysis ; Oceans and Seas
    • Abstract:
      Ocean acidification, a decrease in ocean pH with increasing anthropogenic CO2 concentrations, is expected to affect many marine animals. To examine the effects of decreased pH on snow crab (Chionoecetes opilio), a commercial species in Alaska, we reared ovigerous females in one of three treatments: Ambient pH (~8.1), pH 7.8, and pH 7.5, through two annual reproductive cycles. Morphometric changes during development and hatching success were measured for embryos both years and calcification was measured for the adult females at the end of the 2-year experiment. Embryos and larvae analyzed in year one were from oocytes developed, fertilized, and extruded in situ, whereas embryos and larvae in year two were from oocytes developed, fertilized, and extruded under acidified conditions in the laboratory. In both years, larvae were exposed to the same pH treatments in a fully crossed experimental design. Starvation-survival, morphology, condition, and calcium/magnesium content were assessed for larvae. Embryo morphology during development, hatching success, and fecundity were unaffected by pH during both years. Percent calcium in adult females' carapaces did not differ among treatments at the end of the experiment. In the first year, starvation-survival of larvae reared at Ambient pH but hatched from embryos reared at reduced pH was lowered; however, the negative effect was eliminated when the larvae were reared at reduced pH. In the second year, there was no direct effect of either embryo or larval pH treatment, but larvae reared as embryos at reduced pH survived longer if reared at reduced pH. Treatment either did not affect other measured larval parameters, or effect sizes were small. The results from this two-year study suggest that snow crabs are well adapted to projected ocean pH levels within the next two centuries, although other life-history stages still need to be examined for sensitivity and potential interactive effects with increasing temperatures should be investigated.
      Competing Interests: The authors have declared that no competing interests exist.
      (Copyright: This is an open access article, free of all copyright, and may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose. The work is made available under the Creative Commons CC0 public domain dedication.)
    • References:
      J Exp Biol. 2013 Apr 15;216(Pt 8):1412-22. (PMID: 23536589)
      Environ Res. 2019 Mar;170:168-177. (PMID: 30583126)
      Ecol Evol. 2013 Dec;3(15):5055-65. (PMID: 24455136)
      Glob Chang Biol. 2021 Jul;27(14):3272-3281. (PMID: 33872435)
      Ecology. 2008 Feb;89(2):418-27. (PMID: 18409431)
      Nature. 2003 Sep 25;425(6956):365. (PMID: 14508477)
      Physiol Biochem Zool. 2015 Sep-Oct;88(5):494-507. (PMID: 26658247)
      Mar Pollut Bull. 2013 Apr 15;69(1-2):38-47. (PMID: 23434384)
      Oecologia. 1984 Jun;62(3):289-298. (PMID: 28310880)
      Sci Adv. 2018 Jun 06;4(6):eaar8028. (PMID: 29881778)
      BMC Genomics. 2017 Jun 2;18(1):431. (PMID: 28578697)
      Ecology. 2012 Dec;93(12):2758-68. (PMID: 23431605)
      Comp Biochem Physiol Part D Genomics Proteomics. 2021 Sep;39:100868. (PMID: 34171686)
      Sci Total Environ. 2019 Nov 1;689:322-331. (PMID: 31277000)
      Ecol Lett. 2010 Nov;13(11):1419-34. (PMID: 20958904)
      Mar Pollut Bull. 2020 Apr;153:111006. (PMID: 32275552)
      Glob Chang Biol. 2015 Jun;21(6):2261-71. (PMID: 25430823)
      Glob Chang Biol. 2013 Jun;19(6):1884-96. (PMID: 23505245)
      Proc Biol Sci. 2008 Aug 7;275(1644):1767-73. (PMID: 18460426)
      Mol Ecol. 2016 Apr;25(8):1895-904. (PMID: 26454152)
      PLoS One. 2011 Jan 17;6(1):e14521. (PMID: 21264208)
      Metabolites. 2021 Aug 30;11(9):. (PMID: 34564400)
      J Exp Biol. 1998 Jan;201 (Pt 1):43-55. (PMID: 9390935)
      J Exp Biol. 2021 Feb 5;224(Pt 3):. (PMID: 33436365)
      PLoS One. 2016 Feb 09;11(2):e0148477. (PMID: 26859148)
      Conserv Biol. 2020 Jun;34(3):611-621. (PMID: 31663172)
      Glob Chang Biol. 2013 Nov;19(11):3317-26. (PMID: 23818389)
      Biol Bull. 2007 Aug;213(1):67-75. (PMID: 17679721)
      Environ Sci Technol. 2014 Oct 21;48(20):12275-84. (PMID: 25225957)
      PLoS One. 2013 Apr 04;8(4):e60959. (PMID: 23593357)
      Proc Biol Sci. 2015 Jul 7;282(1810):. (PMID: 26108629)
      Glob Chang Biol. 2019 Dec;25(12):4105-4115. (PMID: 31554025)
    • Accession Number:
      SY7Q814VUP (Calcium)
      142M471B3J (Carbon Dioxide)
    • Publication Date:
      Date Created: 20231018 Date Completed: 20231023 Latest Revision: 20240927
    • Publication Date:
      20240927
    • Accession Number:
      PMC10584120
    • Accession Number:
      10.1371/journal.pone.0276360
    • Accession Number:
      37851644