Slave nodes and the controllability of metabolic networks

TL;DR

This study demonstrates that controlling the expression level of a single reaction in E. coli's metabolic network can largely determine the cell's growth and behavior, revealing potential control points within complex biological systems.

Contribution

It introduces a theoretical framework showing that individual reactions can serve as control points for entire metabolic networks, expanding understanding of cellular regulation.

Findings

A single reaction's expression can control cellular growth.

Many reactions exhibit canalizing interactions.

Methodology offers new insights into network dynamics.

Abstract

Recent work on synthetic rescues has shown that the targeted deletion of specific metabolic genes can often be used to rescue otherwise non-viable mutants. This raises a fundamental biophysical question: to what extent can the whole-cell behavior of a large metabolic network be controlled by constraining the flux of one or more reactions in the network? This touches upon the issue of the number of degrees of freedom contained by one such network. Using the metabolic network of Escherichia coli as a model system, here we address this question theoretically by exploring not only reaction deletions, but also a continuum of all possible reaction expression levels. We show that the behavior of the metabolic network can be largely manipulated by the pinned expression of a single reaction. In particular, a relevant fraction of the metabolic reactions exhibits canalizing interactions, in that the specification of one reaction flux determines cellular growth as well as the fluxes of most other reactions in optimal steady states. The activity of individual reactions can thus be used as surrogates to monitor and possibly control cellular growth and other whole-cell behaviors. In addition to its implications for the study of control processes, our methodology provides a new approach to study how the integrated dynamics of the entire metabolic network emerges from the coordinated behavior of its component parts.