RT Journal Article
SR Electronic
T1 Evolution leads to emergence: An analysis of protein interactomes across the tree of life
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 2020.05.03.074419
DO 10.1101/2020.05.03.074419
A1 Erik Hoel
A1 Brennan Klein
A1 Anshuman Swain
A1 Ross Grebenow
A1 Michael Levin
YR 2020
UL http://biorxiv.org/content/early/2020/05/03/2020.05.03.074419.abstract
AB The internal workings of biological systems are notoriously difficult to understand. Due to the prevalence of noise and degeneracy in evolved systems, in many cases the workings of everything from gene regulatory networks to protein-protein interactome networks remain black boxes. One consequence of this black-box nature is that it is unclear at which scale to analyze biological systems to best understand their function. We analyzed the protein interactomes of over 1800 species, containing in total 8,782,166 protein-protein interactions, at different scales. We demonstrate the emergence of higher order ‘macroscales’ in these interactomes and that these biological macroscales are associated with lower noise and degeneracy and therefore lower uncertainty. Moreover, the nodes in the interactomes that make up the macroscale are more resilient compared to nodes that do not participate in the macroscale. These effects are more pronounced in interactomes of Eukaryota, as compared to Prokaryota. This points to plausible evolutionary adaptation for macroscales: biological networks evolve informative macroscales to gain benefits of both being uncertain at lower scales to boost their resilience, and also being ‘certain’ at higher scales to increase their effectiveness at information transmission. Our work explains some of the difficulty in understanding the workings of biological networks, since they are often most informative at a hidden higher scale, and demonstrates the tools to make these informative higher scales explicit.Competing Interest StatementThe authors have declared no competing interest.