Mosaic convergence of rodent dentitions

Understanding mechanisms responsible for changes in tooth morphology in the course of evolution is an area of investigation common to both paleontology and developmental biology. Detailed analyses of molar tooth crown shape have shown frequent homoplasia in mammalian evolution, which requires accura...

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Bibliographic Details
Published in:PloS one 2008-10, Vol.3 (10), p.e3607-e3607
Main Authors: Lazzari, Vincent, Charles, Cyril, Tafforeau, Paul, Vianey-Liaud, Monique, Aguilar, Jean-Pierre, Jaeger, Jean-Jacques, Michaux, Jacques, Viriot, Laurent
Format: Article
Language:English
Subjects:
Analysis
Animals
Apodemus
Apodemus speciosus
Applied physics
Biodiversity
Biological Evolution
Biology
Chewing
Comparative studies
Computer Simulation
Continuity (mathematics)
Convergence
Cusps
Dentition
Developmental biology
Diet
Earth Sciences
Evolution
Evolution (Biology)
Evolutionary Biology
Evolutionary Biology/Developmental Evolution
Evolutionary Biology/Paleontology
Flattening
Fossils
Locking
Mammals
Mastication
Mastication - physiology
Models, Biological
Molars
Morphogenesis
Morphology
Mosaicism - veterinary
Occlusion
Ontogeny
Paleontology
Pathways
Phylogeny
Preservation
Rodentia
Rodentia - anatomy & histology
Rodents
Sciences of the Universe
Senescence
Studies
Teeth
Tooth - anatomy & histology
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Summary:Understanding mechanisms responsible for changes in tooth morphology in the course of evolution is an area of investigation common to both paleontology and developmental biology. Detailed analyses of molar tooth crown shape have shown frequent homoplasia in mammalian evolution, which requires accurate investigation of the evolutionary pathways provided by the fossil record. The necessity of preservation of an effective occlusion has been hypothesized to functionally constrain crown morphological changes and to also facilitate convergent evolution. The Muroidea superfamily constitutes a relevant model for the study of molar crown diversification because it encompasses one third of the extant mammalian biodiversity. Combined microwear and 3D-topographic analyses performed on fossil and extant muroid molars allow for a first quantification of the relationships between changes in crown morphology and functionality of occlusion. Based on an abundant fossil record and on a well resolved phylogeny, our results show that the most derived functional condition associates longitudinal chewing and non interlocking of cusps. This condition has been reached at least 7 times within muroids via two main types of evolutionary pathways each respecting functional continuity. In the first type, the flattening of tooth crown which induces the removal of cusp interlocking occurs before the rotation of the chewing movement. In the second type however, flattening is subsequent to rotation of the chewing movement which can be associated with certain changes in cusp morphology. The reverse orders of the changes involved in these different pathways reveal a mosaic evolution of mammalian dentition in which direction of chewing and crown shape seem to be partly decoupled. Either can change in respect to strong functional constraints affecting occlusion which thereby limit the number of the possible pathways. Because convergent pathways imply distinct ontogenetic trajectories, new Evo/Devo comparative studies on cusp morphogenesis are necessary.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0003607