A Mechanism of Extreme Growth and Reliable Signaling in Sexually Selected Ornaments and Weapons

Many male animals wield ornaments or weapons of exaggerated proportions. We propose that increased cellular sensitivity to signaling through the insulin/insulin-like growth factor (IGF) pathway may be responsible for the extreme growth of these structures. We document how rhinoceros beetle horns, a...

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Published in	Science (American Association for the Advancement of Science) Vol. 337; no. 6096; pp. 860 - 864
Main Authors	Emlen, Douglas J., Warren, Ian A., Johns, Annika, Dworkin, Ian, Lavine, Laura Corley
Format	Journal Article
Language	English
Published	Washington, DC American Association for the Advancement of Science 17.08.2012 The American Association for the Advancement of Science
Subjects	Animal wings Animals antlers Beetles Biological and medical sciences Biological evolution birds Body size breeding Breeding status Cell growth Coleoptera Coleoptera - anatomy & histology Coleoptera - genetics Coleoptera - growth & development Deer Evolution Fitness Fundamental and applied biological sciences. Psychology Gene Knockdown Techniques Genetics of eukaryotes. Biological and molecular evolution Genitalia Growth traits Horns Horns - anatomy & histology Horns - growth & development insulin Insulin - physiology Insulin-like growth factors Male Male animals Mating Preference, Animal mechanistic models Molecular Sequence Data Online Pathways Phenotypic traits Receptor, Insulin - genetics Receptor, Insulin - physiology Sexual selection Signal Transduction Somatomedins - physiology Weapons Insulin like growth factor Vertebrata Secondary sexual character Sexual selection Biological evolution Morphology Male Invertebrata Mechanism of action
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Abstract	Many male animals wield ornaments or weapons of exaggerated proportions. We propose that increased cellular sensitivity to signaling through the insulin/insulin-like growth factor (IGF) pathway may be responsible for the extreme growth of these structures. We document how rhinoceros beetle horns, a sexually selected weapon, are more sensitive to nutrition and more responsive to perturbation of the insulin/IGF pathway than other body structures. We then illustrate how enhanced sensitivity to insulin/IGF signaling in a growing ornament or weapon would cause heightened condition sensitivity and increased variability in expression among individuals—critical properties of reliable signals of male quality. The possibility that reliable signaling arises as a by-product of the growth mechanism may explain why trait exaggeration has evolved so many different times in the context of sexual selection.
AbstractList	Exaggerated ornaments such as beetle horns, deer antlers, and extreme tail lengths in birds are typically assumed to be subject to sexual selection because they signal the quality of an individual's breeding status—but how? Emlen et al. (p. 860 , published online 26 July) present a general mechanistic model for the evolution of exaggerated traits, proposing that sensitivity to the insulin response pathway can explain variation among individuals. The exaggerated size of such ornaments and their increased variability between individuals are a result of sexual selection for traits that are honest signals of the fitness of the individual. Rhinoceros beetle horns, a sexually selected weapon, are more sensitive to nutrition and reliably indicate male quality. Many male animals wield ornaments or weapons of exaggerated proportions. We propose that increased cellular sensitivity to signaling through the insulin/insulin-like growth factor (IGF) pathway may be responsible for the extreme growth of these structures. We document how rhinoceros beetle horns, a sexually selected weapon, are more sensitive to nutrition and more responsive to perturbation of the insulin/IGF pathway than other body structures. We then illustrate how enhanced sensitivity to insulin/IGF signaling in a growing ornament or weapon would cause heightened condition sensitivity and increased variability in expression among individuals—critical properties of reliable signals of male quality. The possibility that reliable signaling arises as a by-product of the growth mechanism may explain why trait exaggeration has evolved so many different times in the context of sexual selection. Many male animals wield ornaments or weapons of exaggerated proportions. We propose that increased cellular sensitivity to signaling through the insulin/insulin-like growth factor (IGF) pathway may be responsible for the extreme growth of these structures. We document how rhinoceros beetle horns, a sexually selected weapon, are more sensitive to nutrition and more responsive to perturbation of the insulin/IGF pathway than other body structures. We then illustrate how enhanced sensitivity to insulin/IGF signaling in a growing ornament or weapon would cause heightened condition sensitivity and increased variability in expression among individuals—critical properties of reliable signals of male quality. The possibility that reliable signaling arises as a by-product of the growth mechanism may explain why trait exaggeration has evolved so many different times in the context of sexual selection. Exaggerated ornaments such as beetle horns, deer antlers, and extreme tail lengths in birds are typically assumed to be subject to sexual selection because they signal the quality of an individual's breeding status--but how? Emlen et al. (p. 860, published online 26 July) present a general mechanistic model for the evolution of exaggerated traits, proposing that sensitivity to the insulin response pathway can explain variation among individuals. The exaggerated size of such ornaments and their increased variability between individuals are a result of sexual selection for traits that are honest signals of the fitness of the individual. [PUBLICATION ABSTRACT] Many male animals wield ornaments or weapons of exaggerated proportions. We propose that increased cellular sensitivity to signaling through the insulin/insulin-like growth factor (IGF) pathway may be responsible for the extreme growth of these structures. We document how rhinoceros beetle horns, a sexually selected weapon, are more sensitive to nutrition and more responsive to perturbation of the insulin/IGF pathway than other body structures. We then illustrate how enhanced sensitivity to insulin/IGF signaling in a growing ornament or weapon would cause heightened condition sensitivity and increased variability in expression among individuals--critical properties of reliable signals of male quality. The possibility that reliable signaling arises as a by-product of the growth mechanism may explain why trait exaggeration has evolved so many different times in the context of sexual selection. [PUBLICATION ABSTRACT] Truthful Embellishments Exaggerated ornaments such as beetle horns, deer antlers, and extreme tail lengths in birds are typically assumed to be subject to sexual selection because they signal the quality of an individual's breeding status—but how? Emlen et al. (p. 860, published online 26 July) present a general mechanistic model for the evolution of exaggerated traits, proposing that sensitivity to the insulin response pathway can explain variation among individuals. The exaggerated size of such ornaments and their increased variability between individuals are a result of sexual selection for traits that are honest signals of the fitness of the individual. Many male animals wield ornaments or weapons of exaggerated proportions. We propose that increased cellular sensitivity to signaling through the insulin/insulin-like growth factor (IGF) pathway may be responsible for the extreme growth of these structures. We document how rhinoceros beetle horns, a sexually selected weapon, are more sensitive to nutrition and more responsive to perturbation of the insulin/IGF pathway than other body structures. We then illustrate how enhanced sensitivity to insulin/IGF signaling in a growing ornament or weapon would cause heightened condition sensitivity and increased variability in expression among individuals--critical properties of reliable signals of male quality. The possibility that reliable signaling arises as a by-product of the growth mechanism may explain why trait exaggeration has evolved so many different times in the context of sexual selection.Many male animals wield ornaments or weapons of exaggerated proportions. We propose that increased cellular sensitivity to signaling through the insulin/insulin-like growth factor (IGF) pathway may be responsible for the extreme growth of these structures. We document how rhinoceros beetle horns, a sexually selected weapon, are more sensitive to nutrition and more responsive to perturbation of the insulin/IGF pathway than other body structures. We then illustrate how enhanced sensitivity to insulin/IGF signaling in a growing ornament or weapon would cause heightened condition sensitivity and increased variability in expression among individuals--critical properties of reliable signals of male quality. The possibility that reliable signaling arises as a by-product of the growth mechanism may explain why trait exaggeration has evolved so many different times in the context of sexual selection. Truthful EmbellishmentsExaggerated ornaments such as beetle horns, deer antlers, and extreme tail lengths in birds are typically assumed to be subject to sexual selection because they signal the quality of an individual's breeding status-but how? Emlen et al. (p. 860, published online 26 July) present a general mechanistic model for the evolution of exaggerated traits, proposing that sensitivity to the insulin response pathway can explain variation among individuals. The exaggerated size of such ornaments and their increased variability between individuals are a result of sexual selection for traits that are honest signals of the fitness of the individual.
Author	Warren, Ian A. Johns, Annika Emlen, Douglas J. Dworkin, Ian Lavine, Laura Corley
Author_xml	– sequence: 1 givenname: Douglas J. surname: Emlen fullname: Emlen, Douglas J. – sequence: 2 givenname: Ian A. surname: Warren fullname: Warren, Ian A. – sequence: 3 givenname: Annika surname: Johns fullname: Johns, Annika – sequence: 4 givenname: Ian surname: Dworkin fullname: Dworkin, Ian – sequence: 5 givenname: Laura Corley surname: Lavine fullname: Lavine, Laura Corley
BackLink	http://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=26264629$$DView record in Pascal Francis https://www.ncbi.nlm.nih.gov/pubmed/22837386$$D View this record in MEDLINE/PubMed
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Snippet	Many male animals wield ornaments or weapons of exaggerated proportions. We propose that increased cellular sensitivity to signaling through the... Exaggerated ornaments such as beetle horns, deer antlers, and extreme tail lengths in birds are typically assumed to be subject to sexual selection because... Truthful EmbellishmentsExaggerated ornaments such as beetle horns, deer antlers, and extreme tail lengths in birds are typically assumed to be subject to... Truthful Embellishments Exaggerated ornaments such as beetle horns, deer antlers, and extreme tail lengths in birds are typically assumed to be subject to...
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SubjectTerms	Animal wings Animals antlers Beetles Biological and medical sciences Biological evolution birds Body size breeding Breeding status Cell growth Coleoptera Coleoptera - anatomy & histology Coleoptera - genetics Coleoptera - growth & development Deer Evolution Fitness Fundamental and applied biological sciences. Psychology Gene Knockdown Techniques Genetics of eukaryotes. Biological and molecular evolution Genitalia Growth traits Horns Horns - anatomy & histology Horns - growth & development insulin Insulin - physiology Insulin-like growth factors Male Male animals Mating Preference, Animal mechanistic models Molecular Sequence Data Online Pathways Phenotypic traits Receptor, Insulin - genetics Receptor, Insulin - physiology Sexual selection Signal Transduction Somatomedins - physiology Weapons
Title	A Mechanism of Extreme Growth and Reliable Signaling in Sexually Selected Ornaments and Weapons
URI	https://www.jstor.org/stable/23268384 https://www.ncbi.nlm.nih.gov/pubmed/22837386 https://www.proquest.com/docview/1033734437 https://www.proquest.com/docview/1034518149 https://www.proquest.com/docview/1551641829 https://www.proquest.com/docview/1808084487 https://www.proquest.com/docview/2000341693
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