Hostname: page-component-6b88cc9666-5vvpm Total loading time: 0 Render date: 2026-02-14T13:14:22.278Z Has data issue: false hasContentIssue false
  • English
  • Français

Demise of the middle Paleozoic crinoid fauna: a single extinction event or rapid faunal turnover?

Published online by Cambridge University Press: 08 February 2016

William I. Ausich
Affiliation:
Department of Geological Sciences, The Ohio State University, Columbus, Ohio 43210
Thomas W. Kammer
Affiliation:
Department of Geology and Geography, West Virginia University, Post Office Box 6300, Morgantown, West Virginia 26506-6300
Tomasz K. Baumiller
Affiliation:
Department of Earth and Planetary Sciences, Harvard University, Cambridge, Massachusetts 02138

Abstract

Macroevolutionary change from the Middle to the Late Paleozoic crinoid fauna was not the result of mass extinction. The presumption that the decline of the middle Paleozoic crinoid fauna was from a single mass extinction event was tested using seriation, multidimensional scaling (MDS), binomial analysis, and bootstrapping simulations on a data set which is a comprehensive revision of old faunal lists. The data for these analyses were based on temporal distributions of 214 species from 69 late Osagean and early Meramecian localities from the midcontinental United States. The time under consideration is subdivided into seven informal intervals using MDS in conjunction with biostratigraphy. Seriation of species ranges into these intervals results in a gradual pattern of faunal turnover, and sampling bias can be eliminated as a cause for this more gradual pattern. MDS analysis of the crinoid range data is similar to MDS simulations using data with continuous, monotonic species turnover and dissimilar to a simulated mass extinction. Binomial analysis and bootstrapping demonstrate that the observed number of extinctions at the putative extinction boundary were not unusually high. All methods agree that extinctions throughout this time were high but spanned several time intervals and that rapid, monotonic faunal turnover describes the data better than mass extinction. Macroevolutionary processes other than mass extinction and microevolutionary processes must have dictated the character and composition of this remarkable faunal transition among the Crinoidea.

Information

Type
Research Article
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.)

Article purchase

Temporarily unavailable

References

Literature Cited

Ausich,W. I., andKammer,T. W.1990.Systematics and phylogeny of the late Osagean and Meramecian crinoidsPlatycrinites andEucladocrinus from the Mississippian stratotype region.Journal of Paleontology64:759778.CrossRefGoogle Scholar
Ausich,W. I., andKammer,T. W.1991a.Late Osagean and MeramecianActinocrinites from the Mississippian stratotype region (Echinodermata: Crinoidea).Journal of Paleontology65:485499.CrossRefGoogle Scholar
Ausich,W. I., andKammer,T. W.1991b.Systematic revisions toAorocrinus, Macrocrinus, Paradichocrinus, Strotocrinus, andUperocrinus: Mississippian camerate crinoids from the stratotype region (Echinodermata).Journal of Paleontology65:936944.CrossRefGoogle Scholar
Ausich,W. I., andKammer,T. W.1992a.Dizygocrinus: Mississippian camerate crinoid from the midcontinental United States (Echinodermata).Journal of Paleontology66:637658.CrossRefGoogle Scholar
Ausich,W. I., andKammer,T. W.1992b.Biogeography and evolution among late Osagean-early Meramecian (Lower Mississippian) crinoids in the east-central United States.Geological Society of America Abstracts with Program24:A225.Google Scholar
Ausich,W. I., andMeyer,D. L.1988.Blastoids from the late Osagean Fort Payne Formation (Kentucky and Tennessee).Journal of Paleontology62:269283.CrossRefGoogle Scholar
Ausich,W. I., andMeyer,D. L.1992.Crinoidea Flexibilia (Echinodermata) from the Fort Payne Formation (Lower Mississippian; Kentucky and Tennessee).Journal of Paleontology6:825838.CrossRefGoogle Scholar
Ausich,W. I.,Kammer,T. W., andLane,N. G.1979.Fossil communities of the Borden (Mississippian) delta in Indiana and northern Kentucky.Journal of Paleontology53:11811196.Google Scholar
Baumiller,T. K.1992.Major extinction events in the record of Paleozoic crinoids: new metrics for measuring extinction intensities.Geological Society of America Abstracts with Program24:A95.Google Scholar
Brower,J. C.1985.Archaeological seriation of an original data matrix. Pp.95108inGradstein,F. M., ed.Quantitative stratigraphy.Reidel,Dordrecht, Holland.Google Scholar
Brower,J. C., andBussey,D. T.1985.A comparison of five quantitative techniques for biostratigraphy. Pp.279306inGradstein,F. M., ed.Quantitative stratigraphy.Reidel,Dordrecht, Holland.Google Scholar
Chesnut,D. R.Jr., andEttensohn,F. R.1988.Hombergian (Chesterian) Echinoderm paleontology and paleoecology, south-central Kentucky.Bulletins of American Paleontology95:1102.Google Scholar
Collinson,C.,Rexroad,C. B., andThompson,T. L.1971.Conodont zonation of the North American Mississippian.Geological Society of America Memoir127:353395.CrossRefGoogle Scholar
Dillon,W. R., andGoldstein,M.1984.Multivariate analysis, methods and applications.Wiley and Sons,New York.Google Scholar
Donovan,S. K.1989.The significance of the British Ordovician crinoid fauna.Modern Geology13:243255.Google Scholar
Eckert,J. D.1988.Late Ordovician extinction of North American and British crinoids.Lethaia21:147167.CrossRefGoogle Scholar
Efron,B.1982.The jacknife, the bootstrap and other sampling plans.Society for Industrial and Applied Mathematics,Philadelphia.Google Scholar
Gauch,H. G.1982.Multivariate analysis in community ecology.Cambridge University Press.CrossRefGoogle Scholar
Gould,S. J.1985.The paradox of the first tier: an agenda for paleobiology.Paleobiology11:212.CrossRefGoogle Scholar
Hall,J.1857.On the Carboniferous limestones of the Mississippi Valley.American Association for the Advancement of Science Proceedings10:5169and The American Journal of Science and Arts, 2d series, 23:187–203.Google Scholar
Hall,J.1858.Report on the Geological Survey of Iowa embracing the results of investigations made during portions of the years 1855, 1856, 1857.Geological Survey of Iowa1.Google Scholar
Harland,W. B.,Armstrong,R. L.,Cox,A. V.,Craig,L. E.,Smith,A. G., andSmith,D. G.1989.A geologic time scale 1989.Cambridge University Press.Google Scholar
Haugh,B. N.1978.Biodynamic and phyletic paradigms for sensory organs in camerate crinoids.Lethaia11:145173.CrossRefGoogle Scholar
Hirt,D. S.1991.Mississippian brachiopod biostratigraphy and the Osagean-Meramecian boundary in south-central Indiana.Journal of Paleontology65:912916.CrossRefGoogle Scholar
Hohn,M. E.1976.Binary coefficients: a theoretical and empirical study.Mathematical Geology8:137150.CrossRefGoogle Scholar
Hubbard,A. E., andGilinsky,N. L.1992.Mass extinctions as statistical phenomena: an examination of evidence using tests and bootstrapping.Paleobiology18:148159.CrossRefGoogle Scholar
Jablonski,D.1986.Causes and consequences of mass extinctions: a comparative approach. Pp.183229inElliott,D. K., ed.Dynamics of extinction.John Wiley & Sons,New York.Google Scholar
Kammer,T. W., andAusich,W. I.1987.Aerosol suspension feeding and current velocities: distributional controls for late Osagean crinoids.Paleobiology13:379395.CrossRefGoogle Scholar
Kammer,T. W., andAusich,W. I.1992.Advanced cladid crinoids from the middle Mississippian of the east-central United States: primitive-grade calyces.Journal of Paleontology66:461480.CrossRefGoogle Scholar
Kammer,T. W., andAusich,W. I.1993.Advanced cladid crinoids from the middle Mississippian of east-central United States: intermediate-grade calyces.Journal of Paleontology67:614639.CrossRefGoogle Scholar
Kammer,T. W., andAusich,W. I.1994.Advanced cladid crinoids from the middle Mississippian of the east-central United States: Advanced-grade calyces.Journal of Paleontology68:339351.CrossRefGoogle Scholar
Kammer,T. W.,Brenckle,P. L.,Carter,J. L., andAusich,W. I.1990.Redefinition of the Osagean-Meramecian boundary in the Mississippian stratotype region.Palaios5:414431.CrossRefGoogle Scholar
Lane,N. G.1971.Crinoids and reefs.North American Paleontological Convention Proceedings, part J:14301443.Google Scholar
Lane,N. G.1972.Synecology of Middle Mississippian (Carboniferous) crinoid communities in Indiana.Twenty-fourth International Geological Congress, Comptes Rendues Section7:8994.Google Scholar
Lane,N. G., andSevastopulo,G. D.1987.Stratigraphic distribution of Mississippian camerate crinoid genera from North America and western Europe.Courier Forschungs-Institut Senckenberg98:199206.Google Scholar
Lane,N. G., andSevastopulo,G. D.1990.Biogeography of Lower Carboniferous crinoids. Pp.333338inMcKerrow,W. S. andScotese,C. R., eds.Palaeozoic palaeogeography and biogeography.Geological Society of London Memoir.Google Scholar
Laudon,L. R.1948.Osage-Meramec contact.Journal of Geology56:288302.CrossRefGoogle Scholar
Laudon,L. R.1973.Stratigraphic crinoid zonation in Iowa Mississippian rocks.Iowa Academy of Science Proceedings80:288302.Google Scholar
McGhee,G. R.Jr.1989.Catastrophes in the history of life. Pp.2650inAllen,K. C. andBriggs,D. E. G., eds.Evolution and the fossil record.Belhaven Press,London.Google Scholar
Raup,D. M.1992.Large-body impact and extinction in the Phanerozoic,Paleobiology18:8088.CrossRefGoogle ScholarPubMed
Raup,D. M., andSepkoski,J. J.Jr.1982.Mass extinctions in the marine fossil record.Science215:15011503.CrossRefGoogle ScholarPubMed
Rexroad,C. B., andCollinson,C.1965.Conodonts from the Keokuk, Warsaw, and Salem formations (Mississippian) of Illinois.Illinois State Geological Survey Circular388.Google Scholar
Rexroad,C. B., andScott,A. J.1964.Conodont zones in the Rockford Limestone and the lower part of the New Providence Shale (Mississippian) in Indiana.Indiana Geological Survey Bulletin30.Google Scholar
Rohlf,F. J.1985.Numerical taxonomy system of multivariate statistical programs: manual.State University of New York, Stony Brook.Google Scholar
Sepkoski,J. J.Jr.1982.Mass extinctions in the Phanerozoic oceans: a review.Geological Society of America Special Paper190:283289.CrossRefGoogle Scholar
Shaver,R. H.,coordinator.1985.Midwestern basin and arches region: correlation of stratigraphic units of North America (COSUNA) Project.American Association of Petroleum Geologists.Google Scholar
Signor,P. W., andLipps,J. H.1982.Sampling bias, gradual extinction patterns, and catastrophes in the fossil record. Pp.291296inSilver,L. T. andSchultz,P. H., eds.Geological implications of impacts of large asteroids and comets on the Earth.Geological Society of America Special Paper 190.CrossRefGoogle Scholar
Termier,G., andTermier,H.1950.Paléontologie Marocaine II. Invertébres de l'Ere Primaire.Morocco Geological Survey Notes and Memoirs69,391 p.Google Scholar
Wanner,J.1914-1929.Paläontologie von Timor (16 volumes).Erwin Nagele,Stuttgart.Google Scholar
Waters,J. A., andMaples,C. G.1991.Mississippian pelmatozoan community reorganization: a predation-mediated faunal change.Paleobiology17:400410.CrossRefGoogle Scholar
Webster,G. D.1987.Permian crinoids from the type-section of the Callytharra Formation, Callytharra Springs, Western Australia.Alcheringa11:95135.CrossRefGoogle Scholar
Webster,G. D.1990.New Permian crinoids from Australia.Palaeontology33:4974.Google Scholar
Welch,J. R., andLane,N. G.1977.A new crinoid fauna from the Harrodsburg Limestone (Mississippian) of southern Indiana.Indiana Academy of Sciences Proceedings86:285289.Google Scholar
Weller,J. M., et al.1948.Correlation of the Mississippian formations of North America.Geological Society of America Bulletin59:91196.CrossRefGoogle Scholar