Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-02T19:01:37.645Z Has data issue: false hasContentIssue false
  • English
  • Français

Comparison of in situ mineral-associated lipid compositions in modern invertebrate skeletons: preliminary evidence of dietary and environmental influence

Published online by Cambridge University Press:  20 May 2016

Emily A. CoBabe  and
Amy J. Ptak
Emily A. CoBabe
Affiliation:
Biogeochemistry Laboratory, Department of Geosciences, University of Massachusetts, Amherst, Massachusetts 01003. E-mail: [email protected]
Amy J. Ptak
Affiliation:
Biogeochemistry Laboratory, Department of Geosciences, University of Massachusetts, Amherst, Massachusetts 01003. E-mail: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

Lipids found associated with skeletons represent an important avenue of study in molecular paleontology, because the chemical nature of these compounds means they are often biogenically specific and can survive in the geologic record over millions of years. Though it is clear that these skeletal compounds originate from the mineralizing organism, our understanding of the distributions and nutritional sources of lipids among invertebrates is still limited, requiring that baseline studies of modern taxa be completed to evaluate the potential of skeletal lipids in paleoecological studies.

In this study, skeletal lipids from nine modern invertebrate taxa (five mollusks, a brachiopod, an echinoid, a coral, and a barnacle) were extracted and analyzed. Though the major classes of lipids found in the skeletons are remarkably consistent, the sterol profiles from these organisms contain both dietary and environmental information. The skeletons of filter feeders generally have two to three times the variety of sterols as compared with carnivores and grazers. In addition, specific steroidal contributions from several plant and algal groups (including dinosterol, 22-dehydrocholesterol, and β- and γ-sitosterol) can be identified. The limited nature and distribution of sterols in the carnivore skeleton implies that both sterol-recycling and some degree of molecular selectivity may be occurring in this taxon. Taxa living in nearshore shallow marine habitats have significant sterol contributions from higher plants, while deepwater organisms have relatively little. Since the geologically stable form of sterols often retains the three-dimensional structure necessary to recognize the biological precursor, these compounds may be used for determining the ecology of fossil invertebrates.

Type
Articles
Information
Paleobiology , Volume 25 , Issue 2 , Spring 1999 , pp. 201 - 211
Copyright
Copyright © The Paleontological Society 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Literature Cited

Ba, A. S., Guo, D-A., Norton, R. A., Phillips, S. A. Jr., and Nes, W. D. 1995. Developmental differences in the sterol composition of Solenopsis invicta. Archives of Insect Biochemistry and Physiology 29: 19.CrossRefGoogle Scholar
Bocherens, H., Fizet, M., and Mariotti, A. 1994. Diet, physiology and ecology of fossil mammals as inferred from stable carbon and nitrogen isotope biogeochemistry: implications for Pleistocene bears. Palaeogeography, Palaeoclimatology, Palaeoecology 107: 213225.Google Scholar
Bocherens, H., Koch, P. L., Mariotti, A., Geraads, D., and Jaeger, J. J. 1996. Isotopic biogeochemistry (C13, 18) of mammalian enamel from African Pleistocene homonid sites. Palaios 11: 306318.Google Scholar
CoBabe, E. A. and Pratt, L. M. 1995. Molecular and isotopic compositions of lipids in bivalve shells: a new prospect for molecular paleontology. Geochimica et Cosmochimica Acta 59: 8795.Google Scholar
Djerassi, C. 1981. Recent studies in the marine sterol field. Pure and Applied Chemistry 53: 873890.Google Scholar
Dunstan, G. A., Baillie, H. J., Barrett, S. M., and Volkman, J. K. 1996. Effect of diet on the lipid composition of wile and cultured abalone. Aquaculture 140: 115127.Google Scholar
Eglinton, G. and Hamilton, R. J. 1967. Leaf epicuticular waxes. Science 156: 13221335.Google Scholar
Evershed, R. P., Turner-Walker, G., Hedges, R. E. M., Tuross, N., and Leyden, A. 1995. Preliminary results for the analysis of lipids in ancient bone. Journal of Archeological Sciences. 22: 277290.CrossRefGoogle Scholar
Hare, P. E., Fogel, M. L., Stafford, T. W., Mitchell, A. D., and Hoering, T. C. 1991. The isotopic composition of carbon and nitrogen in individual amino acids isolated from modern and fossil proteins. Journal of Archeological Science 18: 115.Google Scholar
Holden, M. J. and Patterson, G. W. 1982. Taxonomic implication of sterol composition in the genus Chlorella. Lipid 17: 215219.Google Scholar
Koch, P. L., Zachos, J. C., and Gingerich, P. D. 1992. Correlation between isotope records in marine and continental carbon reservoirs near the Paleocene/Eocene boundary. Nature 358: 319322.CrossRefGoogle Scholar
Koch, P. L., Heisinger, J., Moss, C., Carlson, R. W., Fogel, M. L., and Behrensmeyer, A. K. 1995. Isotopic tracking of change in diet and habitat use in African elephants. Science 267: 13401343.CrossRefGoogle ScholarPubMed
Miller, G. H. and Hare, P. E. 1980. Amino acid geochronology: Integrity of the carbonate matrix and potential of molluscan fossils. pp. 415444in Hare, P. E. et al. eds. Biogeochemistry of amino acids. Wiley, New York.Google Scholar
Mourente, G., Medina, A., González, S., and Rodrígues, A. 1995. Variations in lipid content and nutritional status during larval development of the marine shrimp Penaeus kerathurus. Aquaculture 130: 187199.Google Scholar
Nichols, P. D., Jones, G. J., de Leeuw, J. W., and Johns, R. B. 1984. The fatty acid and sterol composition of two marine dinoflagellates. Phytochemistry 23: 10431047.Google Scholar
Ourisson, G., Rohmer, M., and Poralla, K. 1987. Prokaryotic hopanoids and other polyterpanoid sterol surrogates. Annual Review of Microbiology 41: 301333.Google Scholar
Patterson, G. W. 1970. The distribution of sterols in algae. Lipids 6: 120127.Google Scholar
Piretti, M. V., Taioli, F., and Pagliuca, G. 1987. Investigation of the seasonal variations of sterol and fatty acid constituents in the bivalve molluscs Venus gallina and Scapharca inaiquivalvis (Bruguiére). Comparative Biochemistry and Physiolology 88B: 12011208.Google Scholar
Piretti, M. V., Zuppa, F., Pagliuca, G., and Taioli, F. 1988. Investigation of the seasonal variations of fatty acid constituents in selected tissues of the bivalve mollusc Scapharca inaequivalvis (Bruguiére). Comparative Biochemistry and Physiolology 89B: 183187.Google Scholar
Soudant, P., Marty, Y., Moal, J., Robert, R., Quéré, C., Le Coz, J. R., and Samain, J. F. 1996. Effect of food fatty acid and sterol quality on Pecten maximus gonad composition and reproduction process. Aquaculture 143: 361378.Google Scholar
Spiro, B., Greenwood, P. B., Southward, A. J., and Dando, P. R. 1986. 13C/12C ratios in marine invertebrates from reducing sediments: confirmation of nutritional importance of chemoautotrophic endosymbiotic bacteria. Marine Ecological Progress Series 28: 233240.CrossRefGoogle Scholar
Stott, A. W., Evershed, R. P., and Tuross, N. 1997. Compound-specific approach to the δ13C analysis of cholesterol in fossil bone. Organic Geochemistry 26: 99103.CrossRefGoogle Scholar
Teshima, S. 1982. Sterol metabolism. pp. 205216in Pruder, G. D., Langdon, C. J., Conklin, D. E. eds. Biochemical and physiological approaches to shellfish nutrition. Louisiana State University Press, Baton Rouge.Google Scholar
Thompson, R. J. and MacDonald, B. A. 1990. The role of environmental conditions in the seasonal synthesis and utilisation of biochemical energy reserves in the giant scallop, Placopecten magellanicus. Canadian Journal of Zoology 68: 750756.Google Scholar
Tieszen, L. L. and Boutton, T. W. 1988. Stable carbon isotopes in terrestrial ecosystem research. pp. 167195in Rundel, P. W. et al. eds. Stable isotopes in ecological research. Springer, Berlin.Google Scholar
Véron, B., Billard, C., Dauguet, J-C., and Martmann, M-A. 1996. Sterol composition of Phaeodactylum tricornutum as influenced by growth temperature and light spectral quality. Lipids 31: 989994.Google Scholar
Volkman, J. K., Gillan, F. T., and Johns, R. B. 1981. Sources of neutral lipids in a temperate intertidal sediment. Geochimica et Cosmochimica Acta 45: 18171828.Google Scholar
Voogt, P. A. 1972. Lipids and sterol components and metabolism in the mollusca. pp. 245300in Florkin, M., Scheer, B. eds. Chemical zoology, Vol. 7. Academic Press, New York.Google Scholar
Wakeham, S. and Lee, C. 1993. Production, transport, and alteration of particulate organic matter in the marine water column. pp. 145170in Engel, M. H., Macko, S. A. eds. Organic geochemistry. Plenum, New York.Google Scholar
Withers, N. W., Kokke, W. C. M. C., Fenical, W., and Djerassi, C. 1982. Sterol patterns of cultured zooxanthellae isolated from marine invertebrates: synthesis of gorgosterol and 23-desmethylgorgosterol by aposymbiotic algae. Proceedings of the National Academy of Sciences USA 79: 37643768.CrossRefGoogle ScholarPubMed
Zhukova, N. V., Kharlamenko, V. I., Svetashev, V. I., and Rodioniv, I. A. 1992. Fatty acids as markers of bacterial symbionts of marine bivalve molluscs. Journal of Experimental Marine Biology and Ecology 192: 253263.Google Scholar