Can biological complexity be reverse engineered?

Studies in History and Philosophy of Science Part C: Studies in History and Philosophy of Biological and Biomedical Sciences 53:73-83 (2015)
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Abstract

Concerns with the use of engineering approaches in biology have recently been raised. I examine two related challenges to biological research that I call the synchronic and diachronic underdetermination problem. The former refers to challenges associated with the inference of design principles underlying system capacities when the synchronic relations between lower-level processes and higher-level systems capacities are degenerate. The diachronic underdetermination problem regards the problem of reverse engineering a system where the non-linear relations between system capacities and lower-level mechanisms are changing over time. Braun and Marom argue that recent insights to biological complexity leave the aim of reverse engineering hopeless - in principle as well as in practice. While I support their call for systemic approaches to capture the dynamic nature of living systems, I take issue with the conflation of reverse engineering with naïve reductionism. I clarify how the notion of design principles can be more broadly conceived and argue that reverse engineering is compatible with a dynamic view of organisms. It may even help to facilitate an integrated account that bridges the gap between mechanistic and systems approaches.

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10.1016/j.shpsc.2015.03.008

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Citations of this work

Biology meets Physics: Reductionism and Multi-scale Modeling of Morphogenesis.Sara Green & Robert Batterman - 2017 - Studies in History and Philosophy of Science Part C: Studies in History and Philosophy of Biological and Biomedical Sciences 7161:20-34.
The Sum of the Parts: Large-Scale Modeling in Systems Biology.Fridolin Gross & Sara Green - 2017 - Philosophy, Theory, and Practice in Biology 9 (10).
How is cancer complex?Anya Plutynski - 2021 - European Journal for Philosophy of Science 11 (2):1-30.
Can functionality in evolving networks be explained reductively?Ulrich Krohs - 2015 - Studies in History and Philosophy of Science Part C: Studies in History and Philosophy of Biological and Biomedical Sciences 53:94-101.

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References found in this work

Metaphors we live by.George Lakoff & Mark Johnson - 1980 - Chicago: University of Chicago Press. Edited by Mark Johnson.
Models and Analogies in Science.Mary B. Hesse - 1963 - [Notre Dame, Ind.]: University of Notre Dame Press.
Metaphors We Live By.George Lakoff & Mark Johnson - 1980 - Ethics 93 (3):619-621.

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