Differentiated muscles are mandatory for gas-filling of the Drosophila airway system.

Yiwen Wang,Uwe Irion,Tina Cruz,Bernard Moussian

doi:10.1242/bio.013086

Abstract

ABSTRACTAt the end of development, organs acquire functionality, thereby ensuring autonomy of an organism when it separates from its mother or a protective egg. In insects, respiratory competence starts when the tracheal system fills with gas just before hatching of the juvenile animal. Cellular and molecular mechanisms of this process are not fully understood. Analyses of the phenotype of Drosophila embryos with malformed muscles revealed that they fail to gas-fill their tracheal system. Indeed, we show that major regulators of muscle formation like Lame duck and Blown fuse are important, while factors involved in the development of subsets of muscles including cardiac and visceral muscles are dispensable for this process, suggesting that somatic muscles (or parts of them) are essential to enable tracheal terminal differentiation. Based on our phenotypic data, we assume that somatic muscle defect severity correlates with the penetrance of the gas-filling phenotype. This argues that a limiting molecular or mechanical muscle-borne signal tunes tracheal differentiation. We think that in analogy to the function of smooth muscles in vertebrate lungs, a balance of physical forces between muscles and the elasticity of tracheal walls may be decisive for tracheal terminal differentiation in Drosophila.

Highlights

Birth occurs when organs of an organism are differentiated to a point allowing survival outside the protective body of the mother or the egg
Mbl is needed for tracheal gas-filling When we were analysing the phenotype of stage 17 ready-to-hatch embryos homozygous mutant for the mbl gene in order to learn more about the role of this gene on embryo differentiation, we noticed that these animals failed to fill their tracheal tubes with gas (Fig. 1)
Wild-type mbl mechanisms have been reported to be deployed in tracheal cells before gas-filling: degradation of the luminal chitin rod, endocytosis, establishment of a paracellular barrier, cuticle formation and greasing of the lumen surface (Forster and Woods, 2013)

Summary

Introduction

Birth occurs when organs of an organism are differentiated to a point allowing survival outside the protective body of the mother or the egg. In this work we have been following the question whether there is any communication between the organs of an organism during terminal differentiation, i.e. do organs coordinate their differentiation?. At the end of insect embryogenesis, the larva fills its respiratory system with gas, moves coordinately to tear apart the eggshell and eventually hatches. This behaviour implies that the brain, the. Received 23 June 2015; Accepted 2 November 2015 tracheal system, the musculature and the exoskeleton are terminally differentiated i.e. ready to allow or support hatching. We asked whether muscles might influence tracheal terminal differentiation

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Conclusion