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Marine Biology

, Volume 153, Issue 3, pp 327–335 | Cite as

Fine-scale chemical fingerprinting of an open coast crustacean for the assessment of population connectivity

  • Henry S. Carson
  • Steven G. Morgan
  • Peter G. Green
Research Article

Abstract

Chemical fingerprinting techniques recently have been used to track larval dispersal of estuarine species that bear calcified structures, but the applicability of this important approach may be limited on the open coast where chemical signatures may be less distinctive and for the many species that do not retain calcified structures throughout development. Externally brooded embryos of the porcelain crab, Petrolisthes cinctipes, and inductively coupled plasma mass spectrometry were used to determine whether fine-scale variation in trace-elemental composition occurred along an open coast. Embryos were collected from 16 sites from 37.8° to 39.5° north latitude along the Pacific Coast of California, USA during late January and early February 2003. Discriminant function analysis revealed that collection sites, many separated by only a few kilometers along an open coast, could be differentiated with an overall accuracy of 73%, and combining the sites into three regions increased the accuracy to 88%. Thus, distinctive elemental signatures can be detected in open coast species even at a fine scale raising the possibility that larval tags can be developed for many more species than previously thought possible.

Keywords

Inductively Couple Plasma Mass Spectrometer Assignment Accuracy Calcify Structure Discriminant Function Analysis Southern Site 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

Notes

Acknowledgments

We thank Leah Akins for assisting with sample collection. Danielle Zacherl contributed technical advice and the comments of Steve Swearer and two anonymous reviewers greatly improved the manuscript. Tom Young made available the ICP-MS. Jennifer Zarzoso assisted with embryo measurement and staging. Funding was provided by Coastal Environmental Quality Initiative through the University of California, Achievement Rewards for College Scientists, San Diego Chapter and the National Science Foundation (OCE-098196). This is contribution number 2392 of the Bodega Marine Laboratory. The experiments described herein comply with the current laws of the United States of America.

References

  1. Anastasia JR, Morgan SG, Fisher NS (1998) Tagging crustacean larvae: assimilation and retention of trace elements. Limnol Oceanogr 43:362–368CrossRefGoogle Scholar
  2. Becker BJ, Fodrie FJ, McMillan PA, Levin LA (2005) Spatial and temporal variation in trace elemental fingerprints of mytilid mussel shells: a precursor to invertebrate larval tracking. Limnol Oceanogr 50:48–61CrossRefGoogle Scholar
  3. Becker BJ, Levin LA, Fodrie FJ, McMillan PA (2007) Complex larval connectivity patterns among marine invertebrate populations. P Natl Acad Sci USA 104:3267–3272CrossRefGoogle Scholar
  4. Chase Z, Johnson KS, Elrod VA, Plant JN, Fitzwater SE, Pickell L, Sakamoto CM (2005) Manganese and iron distributions off central California influenced by upwelling and shelf width. Mar Chem 95:235–254CrossRefGoogle Scholar
  5. Cover TM, Hart PE (1967) Nearest neighbor pattern classification. IEEE T Inform Theory 13(1):21–27CrossRefGoogle Scholar
  6. DiBacco C, Chadwick DB (2001) Assessing the dispersal and exchange of brachyuran larvae between regions of San Diego bay, California and nearshore coastal habitats using elemental fingerprinting. J Mar Res 59:53–78CrossRefGoogle Scholar
  7. DiBacco C, Levin LA (2000) Development and application of elemental fingerprinting to track the dispersal of marine invertebrate larvae. Limnol Oceanogr 45:871–880CrossRefGoogle Scholar
  8. Faure G (1998) Principles and applications of geochemistry: a comprehensive textbook for geology students, 2nd edn. Prentice Hall, New JerseyGoogle Scholar
  9. Flegal AR, Conaway CH, Scelfo GM, Hibdon SA, Sanudo-Wilhelmy SA (2005) A review of factors influencing measurements of decadal variations in metal contamination in San Francisco Bay, California. Ecotoxicology 14:645–660CrossRefGoogle Scholar
  10. Gillanders BM (2005) Using elemental chemistry of fish otoliths to determine connectivity between estuarine and coastal habitats. Estuar Coast Shelf Sci 64:47–57CrossRefGoogle Scholar
  11. Gonor SL (1970) The larval life histories of four porcellanid anomurans (Crustacea, Decapoda) from Oregon. Master’s thesis, Oregon State University, Corvallis, Oregon, USAGoogle Scholar
  12. Huyer AE (1983) Coastal upwelling in the California Current System. Prog Oceanogr 12:259–284CrossRefGoogle Scholar
  13. Jensen GC (1991) Competency, settling behavior, and postsettlement aggregation by porcelain crab megalopae (Anomura : Porcellanidae). J Exp Mar Biol Ecol 153:49–61CrossRefGoogle Scholar
  14. Lachenbruch PA (1975) Discriminant analysis. Hafner, New YorkGoogle Scholar
  15. Lares ML, Flores-Munoz G, Lara-Lara R (2002) Temporal variability of bioavailable Cd, Hg, Zn, Mn and Al in an upwelling regime. Environ Pollut 120:595–608CrossRefGoogle Scholar
  16. Levin LA (1990) A review of methods for labeling and tracking marine invertebrate larvae. Ophelia 32(1–2):115–144CrossRefGoogle Scholar
  17. Levin LA, Huggett D, Myers P, Bridges T (1993) Rare-earth tagging methods for the study of larval dispersal of marine invertebrates. Limnol Oceanogr 38:346–360CrossRefGoogle Scholar
  18. Morris RH, Abbott DP, Haderlie EC (1980) Intertidal invertebrates of California. Stanford University Press, Palo AltoGoogle Scholar
  19. Nriagu JO (1989) A global assessment of natural sources of atmospheric trace metals. Nature 338:47–49CrossRefGoogle Scholar
  20. Sanudo-Wilhelmy SA, Flegal AR (1991) Trace element distributions in coastal waters along the US-Mexican boundary: relative contributions of natural processes vs. anthropogenic inputs. Mar Chem 33:371–392CrossRefGoogle Scholar
  21. Sanudo-Wilhelmy SA, Flegal AR (1996) Trace metal concentrations in the surf zone and in coastal waters off Baja California, Mexico. Environ Sci Technol 30:1575–1580CrossRefGoogle Scholar
  22. Shanks AL, Eckert GL (2005) Larval loss and life history traits of selected California Current fishes and benthic crustaceans. Ecol Monogr 75:505–524CrossRefGoogle Scholar
  23. Strathmann MF (1987) Reproduction and development of marine invertebrates of the northern Pacific coast. University of Washington Press, SeattleGoogle Scholar
  24. Swearer SE, Caselle JE, Lea DW, Warner RR (1999) Larval retention and recruitment in an island population of coral-reef fish. Nature 402(6763):799–802CrossRefGoogle Scholar
  25. Thorrold SR, Jones GP, Hellberg ME, Burton RS, Swearer SE, Neigel JE, Morgan SG, Warner RR (2002) Quantifying larval retention and connectivity in marine populations with artificial and natural markers. Bull Mar Sci (Suppl) 70:291–308Google Scholar
  26. Warner RR, Swearer SE, Caselle JE, Sheehy M, Paradis G (2005) Natal trace-elemental signatures in the otoliths of an open-coast fish. Limnol Oceanogr 50(5):1529–1542CrossRefGoogle Scholar
  27. Weeks JM, Rainbow PS, Moore PG (1992) The loss, uptake and tissue distribution of copper and zinc during the moult cycle in an ecological series of talitrid amphipods (Crustacea: Amphipoda). Hydrobiologia 245:15–25CrossRefGoogle Scholar
  28. Zacherl DC (2005) Spatial and temporal variation in statolith and protoconch trace elements as natural tags to track larval dispersal. Mar Eco Prog Ser 290:145–163CrossRefGoogle Scholar
  29. Zacherl DC, Manriquez PH, Paradis G, Day RW, Castilla JC, Warner RR, Lea DW, Gaines SD (2003) Trace elemental fingerprinting of gastropod statoliths to study larval dispersal trajectories. Mar Ecol Prog Ser 248:297–303CrossRefGoogle Scholar

Copyright information

© Springer-Verlag 2007

Authors and Affiliations

  • Henry S. Carson
    • 1
  • Steven G. Morgan
    • 2
  • Peter G. Green
    • 3
  1. 1.Department of BiologySan Diego State UniversitySan DiegoUSA
  2. 2.Bodega Marine Laboratory, Department of Environmental Science and PolicyUniversity of CaliforniaDavisUSA
  3. 3.Department of Civil and Environmental EngineeringUniversity of CaliforniaDavisUSA

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