Otolith geochemistry does not reflect dispersal history of clownfish larvae
Otolith geochemistry does not reflect dispersal history of clownfish larvae
Date
2010-06
Authors
Berumen, Michael L.
Walsh, Harvey J.
Raventos, N.
Planes, Serge
Jones, Geoffrey P.
Starczak, Victoria R.
Thorrold, Simon R.
Walsh, Harvey J.
Raventos, N.
Planes, Serge
Jones, Geoffrey P.
Starczak, Victoria R.
Thorrold, Simon R.
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Keywords
Amphiprion percula
Connectivity
Natural markers
Otolith chemistry
Papua New Guinea
Pelagic larval duration
Connectivity
Natural markers
Otolith chemistry
Papua New Guinea
Pelagic larval duration
Abstract
Natural geochemical signatures in calcified structures are commonly employed to retrospectively estimate dispersal pathways of larval fish and invertebrates. However, the accuracy of the approach is generally untested due to the absence of individuals with known dispersal histories. We used genetic parentage analysis (genotyping) to divide 110 new recruits of the orange clownfish, Amphiprion percula, from Kimbe Island, Papua New Guinea, into two groups: “self-recruiters” spawned by parents on Kimbe Island and “immigrants” that had dispersed from distant reefs (>10km away). Analysis of daily increments in sagittal otoliths found no significant difference in PLDs or otolith growth rates between self-recruiting and immigrant larvae. We also quantified otolith Sr/Ca and Ba/Ca ratios during the larval phase using laser ablation inductively coupled plasma mass spectrometry. Again, we found no significant differences in larval profiles of either element between self-recruits and immigrants. Our results highlight the need for caution when interpreting otolith dispersal histories based on natural geochemical tags in the absence of water chemistry data or known-origin larvae with which to test the discriminatory ability of natural tags.
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Author Posting. © The Author(s), 2010. This is the author's version of the work. It is posted here by permission of Springer for personal use, not for redistribution. The definitive version was published in Coral Reefs 29 (2010): 883-891, doi:10.1007/s00338-010-0652-z.