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Origins and escalation of herbivory in fishes: a functional perspective

Published online by Cambridge University Press:  08 April 2016

David R. Bellwood
David R. Bellwood*
Affiliation:
Centre for Coral Reef Biodiversity, Department of Marine Biology, James Cook University, Townsville, Q 4811, Australia. E-mail: David.Bellwood@jcu.edu.au
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Abstract

One of the central goals in paleoecology is to understand the nature and consequences of biotic interactions. In marine systems, it has been argued that one of the major steps in the escalation of biotic interactions was marked by the origins of grazing fishes in the Cenozoic. Here I investigate the origins of herbivory and grazing in marine fishes using analyses of functional morphospace. Closing and opening lever ratios and relative length of the lower jaw are used to construct a plot of functional morphospace, a quantitative description of the potential feeding modes of fishes. Four fish faunas were examined, spanning the Mesozoic and Cenozoic (Triassic, Jurassic, Eocene and Recent). All three fossil faunas are from conservation Lagerstätten in the central Tethys, in the vicinity of coral reefs or coral-bearing hardgrounds. Changes in functional morphospace occupation reveal a marked shift in the Cenozoic, with the appearance of fishes with relatively small forceful jaws. In Recent faunas, this functional morphospace is occupied almost exclusively by grazing herbivores. This taxon-independent morphological signal of herbivory was lacking in the Mesozoic faunas, was first recorded in the Eocene, and persisted throughout the Cenozoic. This suggests that the Cenozoic did indeed witness the appearance and proliferation of herbivory and grazing by marine fishes. The arrival of these piscine herbivores had the potential to fundamentally alter the dynamics of benthic marine communities.

Type
Articles
Information
Paleobiology , Volume 29 , Issue 1 , Winter 2003 , pp. 71 - 83
Copyright
Copyright © The Paleontological Society 

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References

Literature Cited

Arratia, G., and Viohl, G. 1996. Mesozoic fishes: systematics and paleoecology. Verlag Dr. Friedrich Pfeil, Munich.Google Scholar
Applegate, S. P. 1996. An overview of the Cretaceous fishes of the quarries near Tepexi de Rodríguez, Puebla, Mexico. Pp. 529538in Arratia, and Viohl, 1996.Google Scholar
Bannikov, A. F., and Tyler, J. C. 1995. Phylogenetic revision of the fish families Luvaridae and Kushlukiidae (Acanthuroidei), with a new genus and two new species of Eocene luvarids. Smithsonian Contributions to Paleobiology 81:145.Google Scholar
Barthel, K. W., Swinburne, N. H. M., and Morris, S. C. 1990. Solnhofen: a study in Mesozoic palaeontology. Cambridge University Press, Cambridge.Google Scholar
Bellwood, D. R. 1990. A new fossil fish Phyllopharyngodon longipinnis gen. et sp. nov. (family Labridae) from the Eocene, Monte Bolca, Italy. Studi e Ricerche sui Giacimenti Terziari di Bolca, Museo Civico di Storia Naturale di Verona 6:149160.Google Scholar
Bellwood, D. R. 1994. A phylogenetic study of the parrotfishes family Scaridae (Pisces: Labroidei), with a revision of genera. Records of the Australian Museum Supplement No. 20:184.Google Scholar
Bellwood, D. R. 1995. Direct estimate of bioerosion by two parrotfish species Chlorurus gibbus and Chlorurus sordidus on the Great Barrier Reef. Marine Biology 121:419430.Google Scholar
Bellwood, D. R. 1996. The Eocene fishes of Monte Bolca: the earliest coral reef fish assemblage. Coral Reefs 15:1119.Google Scholar
Bellwood, D. R. 1998. What are reef fishes? Comment on the report by D. R. Robertson: do coral-reef fish faunas have a distinctive taxonomic structure? Coral Reefs 17:187189.Google Scholar
Bellwood, D. R., and Choat, J. H. 1990. A functional analysis of grazing in parrotfishes (family Scaridae): the ecological implications. Environmental Biology of Fishes 28:189214.Google Scholar
Bellwood, D. R., and Hoey, A.In press. Feeding in Mesozoic fishes: a functional perspective. In Arratia, G. and Tintori, A., eds. Mesozoic Fishes 3. Verlag Dr. Friedrich Pfeil, Munich.Google Scholar
Bellwood, D. R., and Schultz, O. 1991. A review of the fossil record of the parrotfishes (Labroidei: Scaridae) with a description of a new Calotomus species from the Middle Miocene (Badenian) of Austria. Annalen Naturhistorisches Museum, Wien 92:5571.Google Scholar
Bellwood, D. R., and Wainwright, P. C. 2002. The history and biogeography of fishes on coral reefs. Pp. 532in Sale, 2002.Google Scholar
Blot, J. 1980. La faune ichthyologique des gisements du Monte Bolca (Province de Verone, Italie). Catalogue systématique présentant l'état actuel des recherches concernant cette faune. Bulletin du Muséum National d'Histoire Naturelle 2:339396.Google Scholar
Boucot, A. J. 1990. Evolutionary paleobiology of behavior and coevolution. Elsevier, Amsterdam.Google Scholar
Carpenter, R. C. 1986. Partitioning herbivory and its effects on coral reef algal communities. Ecological Monographs 56:345363.Google Scholar
Choat, J. H. 1991. The biology of herbivorous fishes on coral reefs. Pp. 120155in Sale, P. F.2002.Google Scholar
Choat, J. H., and Bellwood, D. R. 1991. Reef fishes: their history and evolution. Pp. 3961in Sale, 2002.Google Scholar
Coates, A. G., and Jackson, J. B. C. 1985. Morphological themes in the evolution of clonal and aclonal marine invertebrates. Pp. 67106in Jackson, J. B. C., Buss, L. W., and Cook, R. E., eds. Population biology and evolution of clonal organisms. Yale University Press, New Haven, Conn.Google Scholar
Dawson, E. Y. 1966. Marine botany: an introduction. Holt, Rhinehart and Winston, New York.Google Scholar
Foote, M. 1994. Morphological disparity in Ordovician–Devonian crinoids and the early saturation of morphological space. Paleobiology 20:320344.Google Scholar
Foote, M. 1995. Morphological diversification of Paleozoic crinoids. Paleobiology 21:273299.Google Scholar
Foote, M., and Gould, S. J. 1992. Cambrian and recent morphological disparity. Science 258:1816.Google Scholar
Freeman, P. W. 2000. Macroevolution in Microchiroptera: recoupling morphology and ecology with phylogeny. Evolutionary Ecology Research 2:317335.Google Scholar
Fryer, G., and Isles, T. D. 1972. The cichlid fishes of the great lakes of Africa: their biology and evolution. Oliver, and Boyd, , Edinburgh.Google Scholar
Galetto, M. J., and Bellwood, D. R. 1994. Digestion of algae by Stegastes nigricans and Amphiprion akindynos (Pisces: Pomacentridae), with an evaluation of methods used in digestibility studies. Journal of Fish Biology 44:415428.Google Scholar
Goldman, B., and Talbot, F. H. 1976. Aspects of the ecology of coral reef fishes. Pp. 125154in Jones, O. A. and Endean, R., eds. Biology and geology of coral reefs. Academic Press, New York.Google Scholar
Grande, L., and Bemis, W. E. 1998. A comprehensive phylogenetic study of amiid fishes (Amiidae) based on comparative skeletal anatomy: an empirical search for interconnected patterns of natural history. Society of Vertebrate Paleontology Memoir 4. Journal of Vertebrate Paleontology 18(Suppl. to No. 1).Google Scholar
Harper, E. M. 1991. The evolution of the cemented habit in bivalved molluscs. Palaeontology 34:455460.Google Scholar
Horn, M. H. 1989. Biology of marine herbivorous fishes. Oceanography and Marine Biology 27:167272.Google Scholar
Huckins, C.J. F. 1997. Functional linkages among morphology, feeding performance, diet, and competitive ability in molluscivorous sunfish. Ecology 78:24012414.Google Scholar
Hughes, T. P. 1994. Catastrophes, phase shifts, and large-scale degradation of a Caribbean coral reef. Science 265:15471551.Google Scholar
Jadoul, F., Berra, F., and Frisia, S. 1992. Stratigraphic and paleogeographic evolution of a carbonate platform in an extension-al tectonic regime: the example of the Dolomia Principale in Lombardy (Italy). Rivista Italiana di Paleontologia e Stratigrafia 98:2944.Google Scholar
Jadoul, F., Masetti, D., Cirilli, S., Berra, F., Claps, M., and Frisia, S. 1994. Norian-Rhaetian stratigraphy and paleogeographic evolution of the Lombardy Basin (Bergamasc Alps). 15th International Association of Sedimentologists Regional Meeting, Excursion B 1:537. Ischia, Italy.Google Scholar
Jernvall, J., Hunter, J. P., and Fortelius, M. 1996. Molar tooth diversity, disparity, and ecology in Cenozoic ungulate radiations. Science 274:14891492.Google Scholar
Lambers, P. H. 1992. On the ichthyofauna of the Solnhofen Lithographic Limestone (Upper Jurassic, Germany). Rijksuniversiteit Groningen, the Netherlands.Google Scholar
Landini, W., and Sorbini, L. 1996. Ecological and trophic relationships of Eocene Monte Bolca (Pesciara) fish fauna. Cherchi, A., ed. Autecology of selected fossil organisms: achievements and problems. Bollettino della Società Paleontologica Italiana Special Volume 3:105112. Mucchi, Modena.Google Scholar
Lobel, P. S. 1981. Trophic biology of herbivorous reef fishes: alimentary pH and digestive capabilities. Journal of Fish Biology 19:365397.Google Scholar
Long, J. A. 1995. The rise of fishes: 500 million years of evolution. University of New South Wales Press, Sydney.Google Scholar
McCook, L. J., Jompa, J., and Diaz-Pulido, G. 2001. Competition between corals and algae on coral reefs: a review of evidence and mechanisms. Coral Reefs 19:400417.Google Scholar
Meyer, D. L. 1985. Evolutionary implications of predation on Recent comatulid crinoids from the Great Barrier Reef. Paleobiology 11:154164.CrossRefGoogle Scholar
Meyer, D. L., and Macurda, D. B. Jr. 1977. Adaptive radiation of the comatulid crinoids. Paleobiology 3:7482.Google Scholar
Mittelbach, G. G. 1988. Competition among refuging sunfishes and effects of fish density on littoral zone invertebrates. Ecology 69:614623.Google Scholar
Motta, P. J. 1984. Mechanics and functions of jaw protrusion in teleost fishes: a review. Copeia 1984:118.Google Scholar
Nelson, J. S. 1994. Fishes of the world. Wiley, New York.Google Scholar
Nursall, J. R. 1996. Distribution and ecology of pycnodont fishes. Pp. 115124in Arratia, and Viohl, 1996.Google Scholar
Oji, T. 1996. Is predation intensity reduced with increasing depth—evidence from the West Atlantic stalked crinoid Endoxocrinus parrae (Gervais) and implications for the Mesozoic Marine Revolution. Paleobiology 22:339351.Google Scholar
Patterson, C. 1994. Osteichthyes: teleostomi. Pp. 621656in Benton, M. J., ed. The fossil record 2. Chapman and Hall, London.Google Scholar
Purcell, S. W., and Bellwood, D. R. 1993. A functional analysis of food procurement in two surgeonfish species, Acanthurus nigrofuscus and Ctenochaetus striatus (Acanthuridae). Environmental Biology of Fishes 37:139159.Google Scholar
Randall, J. E., Allen, G. R., and Steene, R. C. 1990. Fishes of the Great Barrier Reef and Coral Sea. Crawford House, Bathurst, New South Wales.Google Scholar
Sale, P. F., ed. 2002. Coral reef fishes: dynamics and diversity in a complex ecosystem. Academic Press, San Diego.Google Scholar
Schaeffer, B., and Rosen, D. E. 1961. Major adaptive levels in the evolution of the actinopterygian feeding mechanism. American Zoologist 1:187204.Google Scholar
Smith, A. 1984. Echinoid palaeobiology. Allen and Unwin, London.Google Scholar
Sokal, R. R., and Rohlf, F. J. 1995. Biometry: the principles and practices of statistics in biological research, 3d ed. W. H. Freeman, New York.Google Scholar
Sorbini, L. 1989. I fossili di Bolca. Museo Civico di Storia Naturale di Verona, Verona.Google Scholar
Sorbini, L., and Bannikov, A. F. 1991. The Cretaceous fishes of Nardo. II. An enigmatic spiny-rayed fish. Bolletino della Società Paleontologica Italiana 30:239249.Google Scholar
Stanley, S. M. 1974. What has happened to the articulate brachiopods? Geological Society of America Abstracts with Programs 6:966967.Google Scholar
Stanley, S. M. 1977. Trends, rates and patterns of evolution in the Bivalvia. Pp. 209250in Hallam, A., ed. Patterns of evolution, as illustrated by the fossil record. Elsevier, Amsterdam.Google Scholar
Steneck, R. S. 1983. Escalating herbivory and resulting adaptive trends in calcareous algal crusts. Paleobiology 9:4461.Google Scholar
Steneck, R. S. 1988. Herbivory on coral reefs: a synthesis. Proceedings of the Sixth International Coral Reef Symposium, Townsville, Queensland 1:3749.Google Scholar
Steneck, R. S. 1997. Crustose corallines, other algal functional groups, herbivores and sediments: complex interactions along reef productivity gradients. Proceedings of the Eighth International Coral Reef Symposium, Balboa, Panama 1:695700.Google Scholar
Streelman, J. T., Alfaro, M., Westneat, M. W., Bellwood, D. R., and Karl, S. A. 2002. Evolutionary history of the parrotfishes: biogeography, ecomorphology and comparative diversity. Evolution 56:961971.Google Scholar
Tintori, A. 1981. Two new pycnodonts (Pisces, Actinopterygii) from the Upper Triassic of Lombardy (N. Italy). Rivista Italiana di Paleontologia e Stratigrafia 86:795824.Google Scholar
Tintori, A. 1983. Hypsisomatic Semionotidae (Pisces, Actinopterygii) from the Upper Triassic of Lombardy (N. Italy). Rivista Italiana di Paleontologia e Stratigrafia 88:417442.Google Scholar
Tintori, A. 1992. Fish taphonomy and Triassic anoxic basins from the Alps: a case study. Rivista Italiana di Paleontologia e Stratigrafia 97:393408.Google Scholar
Tintori, A. 1995. Biomechanical fragmentation in shell-beds from the Late Triassic of the Lombardian Basin (Northern Italy). Preliminary Report. Rivista Italiana di Paleontologia e Stratigrafia 101:371380.Google Scholar
Tintori, A. 1996. Paralepidotus ornatus (AGASSIZ 1833–43): a semionotid from the Norian (Late Triassic) of Europe. Pp. 167179in Arratia, and Viohl, 1996.Google Scholar
Tintori, A. 1998. Fish biodiversity in the marine Norian (Late Triassic) of northern Italy: the first Neopterygian radiation. Italian Journal of Zoology 65:193198.Google Scholar
Tintori, A., and Renesto, S. 1983. The Macrosemiidae (Pisces, Actinopterygii) from the Upper Triassic of Lombardy (N. Italy). Rivista Italiana di Paleontologia e Stratigrafia 89:209222.Google Scholar
Van Valkenburgh, B. 1994. Ecomorphological analysis of fossil vertebrates and their paleocommunities. Pp. 140166in Wainwright, and Reilly, 1994.Google Scholar
Van Valkenburgh, B. 1995. Tracking ecology over geological time: evolution within guilds of vertebrates. Trends in Ecology and Evolution 10:7176.Google Scholar
Vermeij, G. J. 1977. The Mesozoic marine revolution: evidence from snails, predators and grazers. Paleobiology 3:245258.Google Scholar
Vermeij, G. J. 1987. Interoceanic differences in architecture and ecology: the effects of history and productivity. Pp. 105in Birkeland, C., ed. Comparison between Atlantic and Pacific tropical marine coastal ecosystems: community structure, ecological processes, and productivity. Results and scientific papers of a UNESCO/COMAR workshop, University of South Pacific, Fiji, 24–29 March 1986. COMAR/UNESCO, Paris.Google Scholar
Vermeij, G. J. and Lindberg, D. R. 2000. Delayed herbivory and the assembly of marine benthic ecosystems. Paleobiology 26:419430.Google Scholar
Viohl, G. 1990. Piscivorous fishes of the Solnhofen lithographic limestone. Pp. 287305in Boucot, A. J., ed. Evolutionary paleobiology of behavior and coevolution. Elsevier, Amsterdam.Google Scholar
Viohl, G. 1996. The paleoenvironment of the Late Jurassic fishes from the southern Franconian Alb (Bavaria, Germany). Pp. 513528in Arratia, and Viohl, 1996.Google Scholar
Wainwright, P. C., and Bellwood, D. R. 2002. Ecomorphology of feeding in coral reef fishes. Pp. 3356in Sale, 2002.Google Scholar
Wainwright, P. C., and Reilly, S. M. 1994. Ecological morphology: integrative organismal biology. University of Chicago Press, Chicago.Google Scholar
Wainwright, P. C., and Richard, B. A. 1995. Predicting patterns of prey use from morphology of fishes. Environmental Biology of Fishes 44:97113.Google Scholar
Wainwright, P. C., Westneat, M. W., and Bellwood, D. R. 2000. Linking feeding behaviour and jaw mechanics in fishes. Pp. 207221in Domenici, P. and Blake, R. W., eds. Biomechanics in animal behaviour. BIOS Scientific, Oxford.Google Scholar
Westneat, M. W. 1994. Transmission of force and velocity in the feeding mechanisms of labrid fishes (Teleostei, Perciformes). Zoomorphology 114:103118.Google Scholar
Williams, D. M., and Hatcher, A. I. 1983. Structure of fish communities on outer slopes of inshore, mid-shelf and outer shelf reefs of the Great Barrier Reef. Marine Ecology Progress Series 10:239250.Google Scholar
Wills, M. A. 1998. Cambrian and recent disparity: the picture from priapulids. Paleobiology 24:177199.Google Scholar
Wills, M. A., Briggs, D. E. G., and Fortey, R. A. 1994. Disparity as an evolutionary index: a comparison of Cambrian and Recent arthropods. Paleobiology 20:93130.Google Scholar
Winterbottom, R. 1974. A descriptive synonymy of the striated muscles of the Teleostei. Proceedings of the Academy of Natural Sciences of Philadelphia 125:225317.Google Scholar
Wood, R. 1999. Reef evolution. Oxford University Press, Oxford.Google Scholar