Ocean warming will mitigate the effects of acidification on calcifying sea urchin larvae (Heliocidaris tuberculata) from the Australian global warming hot spot

The negative effect of ocean change stressors – warming and acidification – on calcifying invertebrate larvae has emerged as a significant impact of global change. We assessed the arm growth response of the echinopluteus larva of Heliocidaris tuberculata to simultaneous exposure to these stressors i...

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Bibliographic Details
Published in:Journal of experimental marine biology and ecology 2013-10, Vol.448, p.250-257
Main Authors: Byrne, Maria, Foo, Shawna, Soars, Natalie A., Wolfe, Kennedy D.L., Nguyen, Hong D., Hardy, Natasha, Dworjanyn, Symon A.
Format: Article
Language:English
Subjects:
Biological and medical sciences
Calcifying larvae
Climatology. Bioclimatology. Climate change
Earth, ocean, space
Echinodermata
Echinoidea
Echinopluteus
Exact sciences and technology
External geophysics
Fundamental and applied biological sciences. Psychology
Global change
Heliocidaris tuberculata
Invertebrates
Marine
Meteorology
Ocean acidification
Ocean warming
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Summary:The negative effect of ocean change stressors – warming and acidification – on calcifying invertebrate larvae has emerged as a significant impact of global change. We assessed the arm growth response of the echinopluteus larva of Heliocidaris tuberculata to simultaneous exposure to these stressors in cross-factorial experiments involving ambient and near future temperatures (control −20°C; +4°C: 24°C) and pHNIST levels (control: pH8.1; −3–7pH units: pH7.6–7.8). The more extreme pH treatment, pH7.4, not a near-future condition, was used to assess tolerance levels. Experiments were designed with respect to present day conditions determined for the habitat of H. tuberculata and future (2100+) conditions for the southeast Australia global warming hot spot. Across near future warming-acidification treatments (24°C/pH7.6–7.8) there was a 5–25% decrease in normal development and, at pH7.4, this increased to 11–33%. Increased temperature facilitated larval growth across all pH treatments with a 20–50% increase in arm length at +4°C across all pH levels. Larval growth was strongly reduced by acidification with a 15–25% decrease in arm length at pH7.4–7.6 at control temperature. Warming mitigated the effect of pH on growth. Both stressors increased larval abnormality and asymmetry. The stunting effect of decreased pH on larval growth is typical of echinoplutei, indicating that similar mechanisms operate across species. The large proportion of normal and larger larvae in the +4°C/pH7.8 treatments indicate that H. tuberculata may tolerate near-future ocean change and this may be facilitated by acclimatization or adaption. •Ocean change studies on marine biota need to consider warming and acidification.•Both stressors increased sea urchin larval abnormality and asymmetry.•Sea urchin larval growth and calcification were strongly reduced by acidification.•Larval growth and calcification was strongly increased by warming.•Warming may mitigate the negative effects of acidification on larval growth.
ISSN:0022-0981
1879-1697
DOI:10.1016/j.jembe.2013.07.016