Symmetry-driven network reconstruction through pseudobalanced coloring optimization

TL;DR

This paper introduces a novel integer programming approach to identify pseudobalanced colorings and repair biological networks by accounting for missing data, enhancing symmetry detection and understanding of complex biological systems.

Contribution

It presents the pseudobalanced coloring problem and an integer programming formulation for network repair, improving symmetry analysis in incomplete biological networks.

Findings

Successfully applied to C. elegans connectome

Outperforms existing missing link prediction methods

Enhances detection of network symmetries

Abstract

Symmetries found through automorphisms or graph fibrations provide important insights in network analysis. Symmetries identify clusters of robust synchronization in the network which improves the understanding of the functionality of complex biological systems. Network symmetries can be determined by finding a {\it balanced coloring} of the graph, which is a node partition in which each cluster of nodes receives the same information (color) from the rest of the graph. In recent work we saw that biological networks such as gene regulatory networks, metabolic networks and neural networks in organisms ranging from bacteria to yeast and humans are rich in fibration symmetries related to the graph balanced coloring. Networks based on real systems, however, are built on experimental data which are inherently incomplete, due to missing links, collection errors, and natural variations within specimens of the same biological species. Therefore, it is fair to assume that some of the existing symmetries were not detected in our analysis. For that reason, a method to find pseudosymmetries and repair networks based on those symmetries is important when analyzing real world networks. In this paper we introduce the {\it pseudobalanced coloring} \eqref{eq:mainip} problem, and provide an integer programming formulation which (a) calculates a pseudobalanced coloring of the graph taking into account the missing data, and (b) optimally repairs the graph with the minimal number of added/removed edges to maximize the symmetry of the graph. We apply our formulation to the {\it C. elegans} connectome to find pseudocoloring and the optimal graph repair. Our solution compares well with a manually curated ground-truth {\it C. elegans} graph as well as solutions generated by other methods of missing link prediction.