Modularity in the mammalian dentition: mice and monkeys share a common dental genetic architecture

The concept of modularity provides a useful tool for exploring the relationship between genotype and phenotype. Here, we use quantitative genetics to identify modularity within the mammalian dentition, connecting the genetics of organogenesis to the genetics of population‐level variation for a pheno...

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Veröffentlicht in:	Journal of experimental zoology. Part B, Molecular and developmental evolution Molecular and developmental evolution, 2011-01, Vol.316B (1), p.21-49
Hauptverfasser:	Hlusko, Leslea J., Sage, Richard D., Mahaney, Michael C.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animal models Animals Biological Evolution Dentition Evolution Fossils Gene Expression Regulation, Developmental Genetic diversity Genotypes Homeobox Incisors Mice Molars Organogenesis Papio Papio - anatomy & histology Papio - genetics Pattern formation Phylogeny pleiotropy Premolars Selection, Genetic Species Specificity Teeth Tooth - anatomy & histology
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container_title	Journal of experimental zoology. Part B, Molecular and developmental evolution
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creator	Hlusko, Leslea J. Sage, Richard D. Mahaney, Michael C.
description	The concept of modularity provides a useful tool for exploring the relationship between genotype and phenotype. Here, we use quantitative genetics to identify modularity within the mammalian dentition, connecting the genetics of organogenesis to the genetics of population‐level variation for a phenotype well represented in the fossil record. We estimated the correlations between dental traits owing to the shared additive effects of genes (pleiotropy) and compared the pleiotropic relationships among homologous traits in two evolutionary distant taxa—mice and baboons. We find that in both mice and baboons, who shared a common ancestor >65 Ma, incisor size variation is genetically independent of molar size variation. Furthermore, baboon premolars show independent genetic variation from incisors, suggesting that a modular genetic architecture separates incisors from these posterior teeth as well. Such genetic independence between modules provides an explanation for the extensive diversity of incisor size variation seen throughout mammalian evolution—variation uncorrelated with equivalent levels of postcanine tooth size variation. The modularity identified here is supported by the odontogenic homeobox code proposed for the patterning of the rodent dentition. The baboon postcanine pattern of incomplete pleiotropy is also consistent with predictions from the morphogenetic field model. J. Exp. Zool. (Mol. Dev. Evol.) 316:21–49, 2011. © 2010 Wiley‐Liss, Inc.
doi_str_mv	10.1002/jez.b.21378
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Such genetic independence between modules provides an explanation for the extensive diversity of incisor size variation seen throughout mammalian evolution—variation uncorrelated with equivalent levels of postcanine tooth size variation. The modularity identified here is supported by the odontogenic homeobox code proposed for the patterning of the rodent dentition. The baboon postcanine pattern of incomplete pleiotropy is also consistent with predictions from the morphogenetic field model. J. Exp. Zool. (Mol. Dev. 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Part B, Molecular and developmental evolution</title><addtitle>J. Exp. Zool</addtitle><description>The concept of modularity provides a useful tool for exploring the relationship between genotype and phenotype. Here, we use quantitative genetics to identify modularity within the mammalian dentition, connecting the genetics of organogenesis to the genetics of population‐level variation for a phenotype well represented in the fossil record. We estimated the correlations between dental traits owing to the shared additive effects of genes (pleiotropy) and compared the pleiotropic relationships among homologous traits in two evolutionary distant taxa—mice and baboons. We find that in both mice and baboons, who shared a common ancestor >65 Ma, incisor size variation is genetically independent of molar size variation. Furthermore, baboon premolars show independent genetic variation from incisors, suggesting that a modular genetic architecture separates incisors from these posterior teeth as well. Such genetic independence between modules provides an explanation for the extensive diversity of incisor size variation seen throughout mammalian evolution—variation uncorrelated with equivalent levels of postcanine tooth size variation. The modularity identified here is supported by the odontogenic homeobox code proposed for the patterning of the rodent dentition. The baboon postcanine pattern of incomplete pleiotropy is also consistent with predictions from the morphogenetic field model. J. Exp. Zool. (Mol. Dev. 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subjects	Animal models Animals Biological Evolution Dentition Evolution Fossils Gene Expression Regulation, Developmental Genetic diversity Genotypes Homeobox Incisors Mice Molars Organogenesis Papio Papio - anatomy & histology Papio - genetics Pattern formation Phylogeny pleiotropy Premolars Selection, Genetic Species Specificity Teeth Tooth - anatomy & histology
title	Modularity in the mammalian dentition: mice and monkeys share a common dental genetic architecture
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