Interruption points in the wing gene regulatory network underlying wing polyphenism evolved independently in male and female morphs in Cardiocondyla ants
Wing polyphenism in ants, which produces a winged female queen caste and a wingless female worker caste, evolved approximately 150 million years ago and has been key to the remarkable success of ants. Approximately 20 million years ago, the myrmicine ant genus Cardiocondyla evolved an additional win...
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Veröffentlicht in: | Journal of experimental zoology. Part B, Molecular and developmental evolution Molecular and developmental evolution, 2019-01, Vol.332 (1-2), p.7-16 |
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Sprache: | eng |
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Zusammenfassung: | Wing polyphenism in ants, which produces a winged female queen caste and a wingless female worker caste, evolved approximately 150 million years ago and has been key to the remarkable success of ants. Approximately 20 million years ago, the myrmicine ant genus Cardiocondyla evolved an additional wing polyphenism among males producing two male morphs: wingless males that fight to enhance mating success and winged males that disperse. Here we show that interruption of rudimentary wing‐disc development in larvae of the ant
Cardiocondyla obscurior occurs further downstream in the network in wingless males as compared with wingless female workers. This pattern is corroborated in
C. kagutsuchi, a species from a different clade within the genus, indicating that late interruption of wing development in males is conserved across
Cardiocondyla. Therefore, our results show that the novel male wing polyphenism was not developmentally constrained by the pre‐existing female wing polyphenism and evolved through independent alteration of interruption points in the wing gene network. Furthermore, a comparison of adult morphological characters in
C. obscurior reveals that developmental trajectories lead to similar morphological trait integration between winged and wingless females, but dramatically different integration between winged and wingless males. This suggests that the alternative sex‐specific developmental routes to achieve winglessness in the genus
Cardiocondyla may have evolved through different selection regimes acting on wingless males and females.
Wingless male larvae have rudimentary wing discs, whereas wingless worker larvae do not. This shows that a novel male wing polyphenism in the ant genus Cardiocondyla evolved through independent alteration of interruption points in the wing gene network underlying wing polyphenism in females. |
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ISSN: | 1552-5007 1552-5015 |
DOI: | 10.1002/jez.b.22834 |