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Supply and demand: How does variation in atmospheric oxygen during development affect insect tracheal and mitochondrial networks?

[Display omitted] •Confocal imaging was used to simultaneously image tracheoles and mitochondria.•Tracheolar and mitochondrial investment were inversely correlated to rearing oxygen.•Insects can vary both supply and demand networks in response to oxygen variation. Atmospheric oxygen is one of the mo...

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Published in:Journal of insect physiology 2018-04, Vol.106 (Pt 3), p.217-223
Main Authors: VandenBrooks, John M., Gstrein, Gregory, Harmon, Jason, Friedman, Jessica, Olsen, Matthew, Ward, Anna, Parker, Gregory
Format: Article
Language:English
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Summary:[Display omitted] •Confocal imaging was used to simultaneously image tracheoles and mitochondria.•Tracheolar and mitochondrial investment were inversely correlated to rearing oxygen.•Insects can vary both supply and demand networks in response to oxygen variation. Atmospheric oxygen is one of the most important atmospheric component for all terrestrial organisms. Variation in atmospheric oxygen has wide ranging effects on animal physiology, development, and evolution. This variation in oxygen has the potential to affect both respiratory systems (the supply side) and mitochondrial networks (the demand side) in animals. Insect respiratory systems supplying oxygen to tissues in the gas phase through blind ended tracheal systems are particularly susceptible to this variation. While the large conducting tracheae have previously been shown to respond developmentally to changes in rearing oxygen, the effect of oxygen on the tracheolar network has been relatively unexplored, especially in adult insects. Similarly, mitochondrial networks that meet energy demand in insects and other animals are dynamic and their enzyme activities have been shown to vary in the presence of oxygen. These two systems together should be under selective pressure to meet the aerobic metabolic requirements of insects. To test this hypothesis, we reared Mito-YFP Drosophila under three different oxygen concentrations hypoxia (12%), normoxia (21%), and hyperoxia (31%) and imaged their tracheolar and mitochondrial networks within their flight muscle using confocal microscopy. In terms of oxygen supply, hypoxia increased mean (mid-length) tracheolar diameters, tracheolar tip diameters, the number of tracheoles per main branch and affected tracheal branching patterns, while the opposite was observed in hyperoxia. In terms of oxygen demand, hypoxia increased mitochondrial investment and mitochondrial to tracheolar volume ratios; while the opposite was observed in hyperoxia. Generally, hypoxia had a stronger effect on both systems than hyperoxia. These results show that insects are capable of developmentally changing investment in both their supply and demand networks to increase overall fitness.
ISSN:0022-1910
1879-1611
DOI:10.1016/j.jinsphys.2017.11.001