Averof Lab

Development, Regeneration and Evolution

Association of tracheal placodes with leg primordia in Drosophila and implications for the origin of insect tracheal systems


Journal article


Franch-Marro, Martín, Averof, Casanova
Development, vol. 133, 2006, pp. 785-790

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APA   Click to copy
Franch-Marro, Martín, Averof, & Casanova. (2006). Association of tracheal placodes with leg primordia in Drosophila and implications for the origin of insect tracheal systems. Development, 133, 785–790.


Chicago/Turabian   Click to copy
Franch-Marro, Martín, Averof, and Casanova. “Association of Tracheal Placodes with Leg Primordia in Drosophila and Implications for the Origin of Insect Tracheal Systems.” Development 133 (2006): 785–790.


MLA   Click to copy
Franch-Marro, et al. “Association of Tracheal Placodes with Leg Primordia in Drosophila and Implications for the Origin of Insect Tracheal Systems.” Development, vol. 133, 2006, pp. 785–90.


BibTeX   Click to copy

@article{franch-marro2006a,
  title = {Association of tracheal placodes with leg primordia in Drosophila and implications for the origin of insect tracheal systems},
  year = {2006},
  journal = {Development},
  pages = {785-790},
  volume = {133},
  author = {Franch-Marro and Martín and Averof and Casanova}
}

Abstract

Adaptation to diverse habitats has prompted the development of distinct organs in different animals to better exploit their living conditions. This is the case for the respiratory organs of arthropods, ranging from tracheae in terrestrial insects to gills in aquatic crustaceans. Although Drosophila tracheal development has been studied extensively, the origin of the tracheal system has been a long-standing mystery. Here, we show that tracheal placodes and leg primordia arise from a common pool of cells in Drosophila, with differences in their fate controlled by the activation state of the wingless signalling pathway. We have also been able to elucidate early events that trigger leg specification and to show that cryptic appendage primordia are associated with the tracheal placodes even in abdominal segments. The association between tracheal and appendage primordia in Drosophila is reminiscent of the association between gills and appendages in crustaceans. This similarity is strengthened by the finding that homologues of tracheal inducer genes are specifically expressed in the gills of crustaceans. We conclude that crustacean gills and insect tracheae share a number of features that raise the possibility of an evolutionary relationship between these structures. We propose an evolutionary scenario that accommodates the available data.