ABSTRACT
Phascolosoma agassizii, a commonly reported species of sipunculan worm, occurs at various depths throughout the north Pacific. However, previous studies have shown that this nominal species is actually comprised of two genetically divergent lineages. Phascolosoma agassizii is isolated to the eastern Pacific, whereas a second species, here referred to Phascolosoma sp., is located in the western Pacific and represents a unique, non-sister taxon to P. agassizii. Both species exhibit the same developmental mode with a long-lived, planktotrophic, pelagosphera larval stage, which may facilitate long-distance dispersal, although developmental timing differs. Using an inter-simple sequence repeat polymerase chain reaction (ISSR-PCR) genetic fingerprinting approach, this study examines non-coding polymorphic regions of the nuclear genomes of P. agassizii from four eastern Pacific populations and of Phascolosoma sp. from six western Pacific locations. Small-scale spatial genetic variation was analysed separately for each coastline using an Analysis of Molecular Variance. The data pointed to the potential presence of fine-scale genetic structure within P. agassizii, and recovered significant genetic structure within Phascolosoma sp. from the western Pacific. This study shows that ISSR-PCR is a relatively fast and cost-effective way to study fine-scale genetic diversity in marine invertebrates, although possible analyses and interpretations of the data are subject to the same limitations as other size polymorphism-based approaches.
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Acknowledgements
We thank Anastasia Maiorova (Zhirmunsky Institute of Marine Biology Far East Branch of the Russian Academy of Science) for providing samples from the Sea of Japan and the Kuril Islands and Christina Piotrowski (California Academy of Sciences) for supplying material from California. Corey Sanders assisted with the lab work. Jaime Alvarado, Heidi de Guzman and Liz Borda provided comments on the manuscript. We would like to thank one anonymous reviewer and the MBRJ subject editor, Gavin Gouws, for their incredibly helpful comments prior to publication. This work was partially supported by grants FEBRAS-CRDF RUB1-2996-11 to AS and Anastasia Maiorova and NSF DEB-1036186 to AS.
Disclosure statement
No potential conflict of interest was reported by the authors.