Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-23T18:13:45.508Z Has data issue: false hasContentIssue false

Community structure of Quaternary coral reefs compared with Recent life and death assemblages

Published online by Cambridge University Press:  20 May 2016

Evan N. Edinger
Affiliation:
Department of Earth Sciences, Laurentian University, Ramsey Lake Road, Sudbury, Ontario P3E 2C6, Canada
John M. Pandolfi
Affiliation:
Department of Paleobiology, National Museum of Natural History, Smithsonian Institution, Washington, D.C. 20560-0121
Russell A. Kelley
Affiliation:
Watermark Films, Pty., Ltd., Post Office Box 1859, Townsville, Queensland 4810, Australia

Abstract

This paper assesses the reliability with which fossil reefs record the diversity and community structure of adjacent Recent reefs. The diversity and taxonomic composition of Holocene raised fossil reefs was compared with those of modern reef coral life and death assemblages in adjacent moderate and low-energy shallow reef habitats of Madang Lagoon, Papua New Guinea. Species richness per sample area and Shannon-Wiener diversity (H′) were highest in the fossil reefs, intermediate in the life assemblages, and lowest in the death assemblages. The taxonomic composition of the fossil reefs was most similar to the combination of the life and death assemblages from the modern reefs adjacent to the two fossil reefs. Depth zonation was recorded accurately in the fossil reefs. The Madang fossil reefs represent time-averaged composites of the combined life and death assemblages as they existed at the time the reef was uplifted.

Because fossil reefs include overlapping cohorts from the life and death assemblages, lagoonal facies of fossil reefs are dominated by the dominant sediment-producing taxa, which are not necessarily the most abundant in the life assemblage. Rare or slow-growing taxa accumulate more slowly than the encasing sediments and are underrepresented in fossil reef lagoons. Time-averaging dilutes the contribution of rare taxa, rather than concentrating their contribution. Consequently, fidelity indices developed for mollusks in sediments yield low values in coral reef death and fossil assemblages. Branching corals dominate lagoonal facies of fossil reefs because they are abundant, they grow and produce sediment rapidly, and most of the sediment they produce is not exported.

Fossil reefs distinguished kilometer-scale variations in community structure more clearly than did the modern life assemblages. This difference implies that fossil reefs may provide a better long-term record of community structure than modern reefs. This difference also suggests that modern kilometer-scale variation in coral reef community structure may have been reduced by anthropogenic degradation, even in the relatively unimpacted reefs of Madang Lagoon. Holocene and Pleistocene fossil reefs provide a time-integrated historical record of community composition and may be used as long-term benchmarks for comparison with modern, degraded, nearshore reefs. Comparisons between fossil reefs and degraded modern reefs display gross changes in community structure more effectively than they demonstrate local extinction of rare taxa.

Type
Articles
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

Aronson, R. B.Precht, W. F. 1997. Stasis, biological disturbance, and community structure of a Holocene reef. Paleobiology 23:326346.Google Scholar
Behrensmeyer, A. K.Kidwell, S. M.Gastaldo, R. A. 2001. Taphonomy and paleobiology. In Erwin, D. H.Wing, S. L., eds. Deep time: Paleobiology‘s perspective. Paleobiology 26(Suppl. to No. 4):103147.Google Scholar
Best, M. M. R.Kidwell, S. M. 2000. Bivalve taphonomy in tropical mixed siliciclastic-carbonate settings. I: Environmental variation in shell condition. Paleobiology 26:80102.Google Scholar
Birkeland, C. E. 1997. Life and death of coral reefs. Chapman and Hall, London.Google Scholar
Boucot, A. J. 1953. Life and death assemblages among fossils. American Journal of Science 251:2540.Google Scholar
Bray, J. R.Curtis, J. T. 1957. An ordination of the upland forest communities of southern Wisconsin. Ecological Monographs 27:325349.Google Scholar
Buddemeier, R. W.Kinzie, R. A. 1976. Coral growth. Oceanography and Marine Biology Annual Review 14:183225.Google Scholar
Chappell, J. 1974. Geology of coral terraces, Huon Peninsula, New Guinea: a study of Quaternary tectonic movements and sea-level changes. Geological Society of America Bulletin 85:533570.2.0.CO;2>CrossRefGoogle Scholar
Clarke, K. R. 1993. Non-parametric multivariate analyses of changes in community structure. Australian Journal of Ecology 18:117143.CrossRefGoogle Scholar
Copper, P. 1988. Ecological succession in Phanerozoic reef ecosystems: is it real? Palaios 3:136152.CrossRefGoogle Scholar
Copper, P. 1997. Articulate brachiopod shellbeds: Silurian examples from Anticosti, Eastern Canada. Geobios 20:133148.CrossRefGoogle Scholar
Crame, J. A. 1996. Late Pleistocene molluscan assemblages from the coral reefs of the Kenya coast. Coral Reef 4:183196.Google Scholar
Edinger, E. N.Risk, M. J. 1999. Reef classification by coral morphology predicts coral reef conservation value. Biological Conservation 92:113.CrossRefGoogle Scholar
Edinger, E. N.Lundberg, J.Risk, M. J. 2000. Mid-Holocene fossil reef at Jepara, Central Java, Indonesia: a benchmark of nearshore reef diversity and composition before human disturbance? Ninth International Coral Reef Symposium, Abstracts, p. 49.Google Scholar
Fagerstrom, J. A. 1987. The evolution of reef communities. Wiley, Toronto.Google Scholar
Fürsich, F. T. 1978. The influence of faunal condensation and mixing on the preservation of fossil benthic communities. Lethaia 11:243250.Google Scholar
Greenstein, B. J.Moffat, H. A. 1996. Comparative taphonomy of Holocene and Pleistocene corals, San Salvador, Bahamas. Palaios 11:5763.Google Scholar
Greenstein, B. J.Pandolfi, J. M. 1997. Preservation of community structure in modern reef coral life and death assemblages of the Florida Keys: implications for the Quaternary record of coral reefs. Bulletin of Marine Science 19:3959.Google Scholar
Greenstein, B. J.Curran, H. A.Pandolfi, J. M. 1998a. Shifting ecological baselines and the demise of Acropora cervicornis in the western North Atlantic and Caribbean province: a Pleistocene perspective. Coral Reefs 17:249261.Google Scholar
Greenstein, B. J.Pandolfi, J. M.Curran, H. A. 1998b. The completeness of the Pleistocene fossil record: implications for stratigraphic adequacy. Pp. 75109in Donovan, S. K., ed., The adequacy of the fossil record. Wiley, London.Google Scholar
Greenstein, B. J.White, A.Curran, H. A. 1998c. Comparison of recent coral life and death assemblages to Pleistocene reef communities: implications for rapid faunal replacement on recent reefs. Carbonates and Evaporites 13:2331.CrossRefGoogle Scholar
Hubbard, D. K. 1997. Reefs as dynamic systems. Pp. 4367in Birkeland, C., ed. Life and death of coral reefs. Chapman and Hall, New York.Google Scholar
Hubbard, D. K.Miller, A. I.Scaturo, D. 1990. Production and cycling of calcium carbonate in a shelf-edge reef system (St. Croix, US Virgin Islands): applications to the nature of reef systems in the fossil record. Journal of Sedimentary Petrology 60:335360.Google Scholar
James, N. F.Bourque, P. A. 1992. Reefs and mounds. Pp. 323347in Walker, R. G.James, N. P., eds. Facies models: response to sea level change. Geological Association of Canada, St. John's, Nfld.Google Scholar
Johnson, R. G. 1965. Pelecypod death assemblages in Tomales Bay, California. Journal of Paleontology 39:8085.Google Scholar
Kidwell, S. M. 1998. Time-averaging in the marine fossil record: overview of strategies and uncertainties. Geobios 30:977995.Google Scholar
Kidwell, S. M. 2001. Ecological fidelity of molluscan death assemblages, in Aller, J. Y.Woodin, S. A.Aller, R. C., eds. Organism–sediment interactions. Belle W. Baruch Library in Marine Science, No. 21. University of South Carolina Press, Columbia (in press).Google Scholar
Kidwell, S. M.Bosence, D. W. J. 1991. Taphonomy and time-averaging of marine shelly faunas. Pp. 115209in Allison, P.Briggs, D. E. G., eds. Taphonomy: releasing the data locked in the fossil record. Plenum, New York.Google Scholar
Kidwell, S. M.Flessa, K. 1995. The quality of the fossil record. Annual Review of Ecology and Systematics 26:269299.Google Scholar
Kowalewski, M. 1996. Time-averaging, overcompleteness, and the quality of the fossil record. Journal of Geology 104:317326.Google Scholar
Kowalewski, M.Goodfriend, G. A.Flessa, K. W. 1998. High-resolution estimates of temporal mixing within shell beds: the evils and virtues of time-averaging. Paleobiology 24:287304.Google Scholar
Loya, Y. 1978. Plotless and transect methods. Pp. 197217in Stoddart, D. R.Johannes, R. E., eds. Coral reefs: research methods. UNESCO, Paris.Google Scholar
Meldahl, K. H.Flessa, K. W.Cutler, A. H. 1997. Time-averaging and postmortem skeletal survival in benthic fossil assemblages: quantitative comparisons among Holocene environments. Paleobiology 23:207229.CrossRefGoogle Scholar
Mesolella, K. J. 1967. Zonation of uplifted Pleistocene coral reefs on Barbados, West Indies. Science 156:638640.Google Scholar
Olszewski, T. 1999. Taking advantage of time-averaging. Paleobiology 25:226238.Google Scholar
Olszewski, T.West, R. 1997. Influence of transportation and time-averaging in fossil assemblages from the Pennsylvanian of Oklahoma. Lethaia 30:315330.Google Scholar
Pandolfi, J. M. 1996. Limited membership in Pleistocene reef coral assemblages from the Huon Peninsula, Papua New Guinea: constancy during global change. Paleobiology 22:152176.Google Scholar
Pandolfi, J. M. 1999. Response of Pleistocene coral reefs to environmental change over long temporal scales. American Zoologist 39:113130.CrossRefGoogle Scholar
Pandolfi, J. M.Greenstein, B. J. 1997a. Taphonomic alteration of reef corals: effects of reef environment and coral growth form. I: The Great Barrier Reef. Palaios 12:2742.Google Scholar
Pandolfi, J. M.Greenstein, B. J. 1997b. Preservation of community structure in death assemblages of deep-water Caribbean reef corals. Limnology and Oceanography 42:15051516.Google Scholar
Pandolfi, J. M.Jackson, J. B. C. 2001. Community structure of Pleistocene coral reefs of Curaçao, Netherlands Antilles. Ecological Monographs 71:4967.Google Scholar
Pandolfi, J. M.Minchin, P. R. 1995. A comparison of taxonomic composition and diversity between reef coral life and death assemblages in Madang Lagoon, Papua New Guinea. Palaeogeography, Palaeoclimatology, Palaeoecology 119:321341.Google Scholar
Paulay, G. 1996. Dynamic clams: changes in the bivalve fauna of Pacific islands as a result of sea-level fluctuations. American Malacological Bulletin 12:4557.Google Scholar
Perrin, C.Bosence, D. W. J.Rosen, B. R. 1995. Quantitative approaches to palaeozonation and palaeobathymetry of corals and coralline algae in Cenozoic reefs. Pp. 181229in Bosence, D. W. J.Allison, P., eds. Marine palaeoenvironmental analysis from fossils. Geological Society of London Special Publication 83.Google Scholar
Peterson, C. H. 1976. Relative abundances of living and dead molluscs in two California lagoons. Lethaia 9:958965.Google Scholar
Rahel, F. J. 1990. The hierarchical nature of community persistence: a problem of scale. American Naturalist 136:328344.Google Scholar
Scoffin, T. P. 1981. Aspects of the preservation of deep and shallow water reefs. Proceedings of the Fourth International Coral Reef Symposium 1:499501.Google Scholar
Scoffin, T. P. 1992. Taphonomy of coral reefs: a review. Coral Reefs 11:5777.Google Scholar
Scoffin, T. P.Tudhope, A. W.Brown, B. E.Changsang, H.Cheeney, R. F. 1992. Patterns and possible environmental controls of skeletogenesis of Porites lutea, South Thailand. Coral Reefs 11:111.Google Scholar
Stearn, C. W.Scoffin, T. P.Martindale, W. 1977. Calcium carbonate budget of a fringing reef on the west coast of Barbados, I. Zonation and productivity. Bulletin of Marine Science 27:479510.Google Scholar
Taylor, J. D. 1978. Faunal response to the instability of reef habitats: Pleistocene molluscan assemblages of Aldabra atoll. Palaeontology 21:130.Google Scholar
Tudhope, R. W.Lea, D. W.Shimmield, G. B.Chilcott, C. P.Scoffin, T. P.Fallick, A. E.Jebb, M. 1997. Climatic records from massive Porites corals in Papua New Guinea: a comparison of skeletal Ba/Ca, Skeletal d18), and coastal rainfall. Proceedings of the Eighth International Coral Reef Symposium 2:17191724.Google Scholar
Tudhope, A. W.Buddemeier, R. W.Chilcott, C. P.Berryman, K. R.Fautin, D. G.Jebb, M.Lipps, J. H.Pearce, R. G.Scoffin, T. P.Shimmield, G. B. 2000. Alternating seismic uplift and subsidence in the late Holocene at Madang, Papua New Guinea: evidence from raised reefs. Journal of Geophysical Research (Solid Earth) 105(B6):1379713807.Google Scholar
Veron, J. E. N. 1993. A biogeographic database of hermatypic corals. Species of the central Indo-Pacific and genera of the world. Australian Institute of Marine Science Monograph 10. Townsville, Australia.Google Scholar
Veron, J. E. N.Pichon, M. 1976. Scleractinia of eastern Australia, Vol. I. Families Thamnasteriidae, Astrocoeniidae, Pocilloporidae. Australian Institute of Marine Science Monograph 1. Townsville, Australia.Google Scholar
Veron, J. E. N.Pichon, M. 1980. Scleractinia of eastern Australia, Vol. III. Families Agariciidae, Siderastreidae, Fungiidae, Oculinidae, Merulinidae, Mussidae, Pectinidae, Caryophylliidae, Dendrophylliidae. Australian Institute of Marine Science Monograph 4. Townsville, Australia.Google Scholar
Veron, J. E. N.Pichon, M. 1982. Scleractinia of eastern Australia, Vol. IV. Family Poritidae. Australian Institute of Marine Science Monograph 5. Townsville, Australia.Google Scholar
Veron, J. E. N.Wallace, C. C. 1984. Scleractinia of eastern Australia, Vol. V. Family Acroporidae. Australian Institute of Marine Science Monograph 6. Townsville, Australia.Google Scholar
Veron, J. E. N.Pichon, M.Wijsman-Best, M. 1977. Scleractinia of eastern Australia, Vol. II. Families Faviidae, Trachyphylliidae. Australian Institute of Marine Science Monograph 3. Townsville, Australia.Google Scholar
Walker, K. R.Alberstadt, L. P. 1975. Ecological succession as an aspect of structure in fossil communities. Paleobiology 1:238257.CrossRefGoogle Scholar
Zuchsin, M.Hohenegger, J.Steininger, F. F. 2000. A comparison of living and dead molluscs on coral reef associated hard substrata in the northern Red Sea—implications for the fossil record. Palaeogeography, Palaeoclimatology, Palaeoecology 159:167190.Google Scholar