Constraint and adaptation in the evolution of carnivoran skull shape
The evolutionary history of the Order Carnivora is marked by episodes of iterative evolution. Although this pattern is widely reported in different carnivoran families, the mechanisms driving the evolution of carnivoran skull morphology remain largely unexplored. In this study we use coordinate-poin...
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| Veröffentlicht in: | Paleobiology 2011-06, Vol.37 (3), p.490-518 |
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| creator | Figueirido, Borja MacLeod, Norman Krieger, Jonathan De Renzi, Miquel Pérez-Claros, Juan Antonio Palmqvist, Paul |
| description | The evolutionary history of the Order Carnivora is marked by episodes of iterative evolution. Although this pattern is widely reported in different carnivoran families, the mechanisms driving the evolution of carnivoran skull morphology remain largely unexplored. In this study we use coordinate-point extended eigenshape analysis (CP-EES) to summarize aspects of skull shape in large fissiped carnivores. Results of these comparisons enable the evaluation of the role of different factors constraining the evolution of carnivoran skull design. Empirical morphospaces derived from mandible anatomy show that all hypercarnivores (i.e., those species with a diet that consists almost entirely of vertebrate flesh) share a set of traits involved in a functional compromise between bite force and gape angle, which is reflected in a strong pattern of morphological convergence. Although the paths followed by different taxa to reach this “hypercarnivore shape-space” differ because of phylogenetic constraints, the morphological signature of hypercarnivory in the mandible is remarkably narrow and well constrained. In contrast, CP-EES of cranial morphology does not reveal a similar pattern of shape convergence among hypercarnivores. This suggests a lesser degree of morphological plasticity in the cranium compared to the mandible, which probably results from a compromise between different functional demands in the cranium (e.g., feeding, vision, olfactory sense, and brain processing) whereas the mandible is only involved in food acquisition and processing. Combined analysis of theoretical and empirical morphospaces for these skull data also show the lower anatomical disparity of felids and hyaenids compared to canids and ursids. This indicates that increasing specialization within the hypercarnivorous niche may constrain subsequent morphological and ecological flexibility. During the Cenozoic, similar skull traits appeared in different carnivoran lineages, generated by similar selection pressures (e.g., toward hypercarnivory) and shared developmental pathways. These pathways were likely the proximate source of constraints on the degree of variation associated with carnivoran skull evolution and on its direction. |
| doi_str_mv | 10.1666/09062.1 |
| format | Article |
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Although this pattern is widely reported in different carnivoran families, the mechanisms driving the evolution of carnivoran skull morphology remain largely unexplored. In this study we use coordinate-point extended eigenshape analysis (CP-EES) to summarize aspects of skull shape in large fissiped carnivores. Results of these comparisons enable the evaluation of the role of different factors constraining the evolution of carnivoran skull design. Empirical morphospaces derived from mandible anatomy show that all hypercarnivores (i.e., those species with a diet that consists almost entirely of vertebrate flesh) share a set of traits involved in a functional compromise between bite force and gape angle, which is reflected in a strong pattern of morphological convergence. Although the paths followed by different taxa to reach this “hypercarnivore shape-space” differ because of phylogenetic constraints, the morphological signature of hypercarnivory in the mandible is remarkably narrow and well constrained. In contrast, CP-EES of cranial morphology does not reveal a similar pattern of shape convergence among hypercarnivores. This suggests a lesser degree of morphological plasticity in the cranium compared to the mandible, which probably results from a compromise between different functional demands in the cranium (e.g., feeding, vision, olfactory sense, and brain processing) whereas the mandible is only involved in food acquisition and processing. Combined analysis of theoretical and empirical morphospaces for these skull data also show the lower anatomical disparity of felids and hyaenids compared to canids and ursids. This indicates that increasing specialization within the hypercarnivorous niche may constrain subsequent morphological and ecological flexibility. During the Cenozoic, similar skull traits appeared in different carnivoran lineages, generated by similar selection pressures (e.g., toward hypercarnivory) and shared developmental pathways. These pathways were likely the proximate source of constraints on the degree of variation associated with carnivoran skull evolution and on its direction.</description><identifier>ISSN: 0094-8373</identifier><identifier>EISSN: 1938-5331</identifier><identifier>DOI: 10.1666/09062.1</identifier><identifier>CODEN: PALBBM</identifier><language>eng</language><publisher>Cambridge, UK: The Paleontological Society</publisher><subject>adaptation ; Adaptations ; biologic evolution ; biometry ; Bites ; Brain ; Canines ; Carnivora ; Carnivores ; Cenozoic ; Chordata ; Convergence ; Data processing ; Diets ; eigenvalues ; Eutheria ; Evolution ; Feeding ; Food processing ; functional morphology ; Geometric shapes ; History ; Jaw ; Mammalia ; Mandible ; morphology ; Niches ; Paleontology ; Phylogenetics ; Phylogeny ; Plasticity (functional) ; regression analysis ; s ; Skull ; Specialization ; statistical analysis ; Teeth ; Tetrapoda ; Theria ; Vertebrata ; vertebrate ; Vision</subject><ispartof>Paleobiology, 2011-06, Vol.37 (3), p.490-518</ispartof><rights>The Paleontological Society</rights><rights>Copyright © The Paleontological Society</rights><rights>GeoRef, Copyright 2020, American Geosciences Institute. 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Abstract, Copyright, The Paleontological Society</rights><rights>2011 The Paleontological Society</rights><rights>Copyright Paleontological Society Summer 2011</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-a495t-17ab8de031eba645603a9d219c78363eee7553abde7110d5e3ae7c2dbc8da6f53</citedby><cites>FETCH-LOGICAL-a495t-17ab8de031eba645603a9d219c78363eee7553abde7110d5e3ae7c2dbc8da6f53</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://bioone.org/doi/pdf/10.1666/09062.1$$EPDF$$P50$$Gbioone$$H</linktopdf><linktohtml>$$Uhttps://www.jstor.org/stable/23014735$$EHTML$$P50$$Gjstor$$H</linktohtml><link.rule.ids>315,781,785,804,26980,27926,27927,52365,58019,58252</link.rule.ids></links><search><creatorcontrib>Figueirido, Borja</creatorcontrib><creatorcontrib>MacLeod, Norman</creatorcontrib><creatorcontrib>Krieger, Jonathan</creatorcontrib><creatorcontrib>De Renzi, Miquel</creatorcontrib><creatorcontrib>Pérez-Claros, Juan Antonio</creatorcontrib><creatorcontrib>Palmqvist, Paul</creatorcontrib><title>Constraint and adaptation in the evolution of carnivoran skull shape</title><title>Paleobiology</title><addtitle>Paleobiology</addtitle><description>The evolutionary history of the Order Carnivora is marked by episodes of iterative evolution. Although this pattern is widely reported in different carnivoran families, the mechanisms driving the evolution of carnivoran skull morphology remain largely unexplored. In this study we use coordinate-point extended eigenshape analysis (CP-EES) to summarize aspects of skull shape in large fissiped carnivores. Results of these comparisons enable the evaluation of the role of different factors constraining the evolution of carnivoran skull design. Empirical morphospaces derived from mandible anatomy show that all hypercarnivores (i.e., those species with a diet that consists almost entirely of vertebrate flesh) share a set of traits involved in a functional compromise between bite force and gape angle, which is reflected in a strong pattern of morphological convergence. Although the paths followed by different taxa to reach this “hypercarnivore shape-space” differ because of phylogenetic constraints, the morphological signature of hypercarnivory in the mandible is remarkably narrow and well constrained. In contrast, CP-EES of cranial morphology does not reveal a similar pattern of shape convergence among hypercarnivores. This suggests a lesser degree of morphological plasticity in the cranium compared to the mandible, which probably results from a compromise between different functional demands in the cranium (e.g., feeding, vision, olfactory sense, and brain processing) whereas the mandible is only involved in food acquisition and processing. Combined analysis of theoretical and empirical morphospaces for these skull data also show the lower anatomical disparity of felids and hyaenids compared to canids and ursids. This indicates that increasing specialization within the hypercarnivorous niche may constrain subsequent morphological and ecological flexibility. During the Cenozoic, similar skull traits appeared in different carnivoran lineages, generated by similar selection pressures (e.g., toward hypercarnivory) and shared developmental pathways. These pathways were likely the proximate source of constraints on the degree of variation associated with carnivoran skull evolution and on its direction.</description><subject>adaptation</subject><subject>Adaptations</subject><subject>biologic evolution</subject><subject>biometry</subject><subject>Bites</subject><subject>Brain</subject><subject>Canines</subject><subject>Carnivora</subject><subject>Carnivores</subject><subject>Cenozoic</subject><subject>Chordata</subject><subject>Convergence</subject><subject>Data processing</subject><subject>Diets</subject><subject>eigenvalues</subject><subject>Eutheria</subject><subject>Evolution</subject><subject>Feeding</subject><subject>Food processing</subject><subject>functional morphology</subject><subject>Geometric 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shape</atitle><jtitle>Paleobiology</jtitle><addtitle>Paleobiology</addtitle><date>2011-06-01</date><risdate>2011</risdate><volume>37</volume><issue>3</issue><spage>490</spage><epage>518</epage><pages>490-518</pages><issn>0094-8373</issn><eissn>1938-5331</eissn><coden>PALBBM</coden><abstract>The evolutionary history of the Order Carnivora is marked by episodes of iterative evolution. Although this pattern is widely reported in different carnivoran families, the mechanisms driving the evolution of carnivoran skull morphology remain largely unexplored. In this study we use coordinate-point extended eigenshape analysis (CP-EES) to summarize aspects of skull shape in large fissiped carnivores. Results of these comparisons enable the evaluation of the role of different factors constraining the evolution of carnivoran skull design. Empirical morphospaces derived from mandible anatomy show that all hypercarnivores (i.e., those species with a diet that consists almost entirely of vertebrate flesh) share a set of traits involved in a functional compromise between bite force and gape angle, which is reflected in a strong pattern of morphological convergence. Although the paths followed by different taxa to reach this “hypercarnivore shape-space” differ because of phylogenetic constraints, the morphological signature of hypercarnivory in the mandible is remarkably narrow and well constrained. In contrast, CP-EES of cranial morphology does not reveal a similar pattern of shape convergence among hypercarnivores. This suggests a lesser degree of morphological plasticity in the cranium compared to the mandible, which probably results from a compromise between different functional demands in the cranium (e.g., feeding, vision, olfactory sense, and brain processing) whereas the mandible is only involved in food acquisition and processing. Combined analysis of theoretical and empirical morphospaces for these skull data also show the lower anatomical disparity of felids and hyaenids compared to canids and ursids. This indicates that increasing specialization within the hypercarnivorous niche may constrain subsequent morphological and ecological flexibility. During the Cenozoic, similar skull traits appeared in different carnivoran lineages, generated by similar selection pressures (e.g., toward hypercarnivory) and shared developmental pathways. These pathways were likely the proximate source of constraints on the degree of variation associated with carnivoran skull evolution and on its direction.</abstract><cop>Cambridge, UK</cop><pub>The Paleontological Society</pub><doi>10.1666/09062.1</doi><tpages>29</tpages></addata></record> |
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| subjects | adaptation Adaptations biologic evolution biometry Bites Brain Canines Carnivora Carnivores Cenozoic Chordata Convergence Data processing Diets eigenvalues Eutheria Evolution Feeding Food processing functional morphology Geometric shapes History Jaw Mammalia Mandible morphology Niches Paleontology Phylogenetics Phylogeny Plasticity (functional) regression analysis s Skull Specialization statistical analysis Teeth Tetrapoda Theria Vertebrata vertebrate Vision |
| title | Constraint and adaptation in the evolution of carnivoran skull shape |
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