Predicting performance and plasticity in the development of respiratory structures and metabolic systems


Meeting Abstract

S6.3-2  Sunday, Jan. 5 14:00  Predicting performance and plasticity in the development of respiratory structures and metabolic systems GREENLEE, Kendra J.*; MONTOOTH, Kristi L.; North Dakota State University, Fargo; Indiana University, Bloomington kendra.greenlee@ndsu.edu

The scaling laws governing metabolism suggest that we can predict metabolic traits across taxonomic scales that span large differences in mass. Yet, scaling relationships can vary with development, body region, and environment. Within species, there is variation in metabolic rate that is independent of mass and which may be explained by genetic variation, the environment or their interaction (i.e., metabolic plasticity). Additionally, some structures, such as the insect tracheal respiratory system, change throughout development and in response to the environment to match the changing functional requirements of the organism. We discuss how study of the development of respiratory function meets multiple challenges set forth by the NSF Grand Challenges Workshop. Development of respiratory system structure and function 1) is inherently stable and yet can respond dynamically to change, 2) is plastic and exhibits sensitivity to environments, and 3) can be examined across multiple scales in time and space. Predicting respiratory performance and plasticity requires quantitative models that integrate information across scales of function from metabolic gene expression and mitochondrial biogenesis to the building of respiratory structures. We present insect models where data are available on the development of the tracheal respiratory system and of metabolic physiology and suggest what is needed to develop predictive models. Incorporating quantitative genetic data will enable mapping of genetic and genetic-by-environment variation onto phenotypes, which is necessary to understand the evolution of respiratory systems and their ability to enable respiratory homeostasis as organisms walk the tightrope between stability and change.

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