Sea urchin fertilization in a warm, acidified high pCO2 ocean across a range of sperm densities

Marine invertebrate gametes are being spawned into an ocean simultaneously warming, acidifying and increasing in pCO2. Decreased pH/increased pCO2 narcotizes sperm indicating that acidification may impair fertilization, exacerbating problems of sperm limitation, with dire implications for marine lif...

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Bibliographic Details
Published in:	Marine Environmental Research
Main Authors:	Byrne, Maria, Soars, Natalie, Selvakumraswamy, Paulina, Dworjanyn, Symon A, Davis, Andrew R
Format:	Article in Journal/Newspaper
Language:	unknown
Published:	ePublications@SCU 2010
Subjects:	Climate change Ocean warming Ocean acidification Sperm concentration Sea urchin Fertilization pH/pCO2 Environmental Sciences
Online Access:	https://epubs.scu.edu.au/esm_pubs/1727 https://doi.org/10.1016/j.marenvres.2009.10.014

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Summary:	Marine invertebrate gametes are being spawned into an ocean simultaneously warming, acidifying and increasing in pCO2. Decreased pH/increased pCO2 narcotizes sperm indicating that acidification may impair fertilization, exacerbating problems of sperm limitation, with dire implications for marine life. In contrast, increased temperature may have a stimulatory effect, enhancing fertilization. We investigated effects of ocean change on sea urchin fertilization across a range of sperm densities. We address two predictions: (1) low pH/increased pCO2 reduces fertilization at low sperm density and (2) increased temperature enhances fertilization, buffering negative effects of acidification and increased pCO2. Neither prediction was supported. Fertilization was only affected by sperm density. Increased acidification and pCO2 did not reduce fertilization even at low sperm density and increased temperature did not enhance fertilization. It is important to identify where vulnerabilities lie across life histories and our results indicate that sea urchin fertilization is robust to climate change stressors. However, developmental stages may be vulnerable to ocean change.

Sea urchin fertilization in a warm, acidified high pCO2 ocean across a range of sperm densities

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