Abstract
AbstractSeveral meso-scale biological intracellular regulatory networks that have specified directionality of interactions have been recently assembled from experimental literature. Directed networks where links are characterized as positive or negative can be converted to systems of differential equations and analyzed as dynamical systems. Such analyses have shown that networks containing only sign-consistent loops, such as positive feed-forward and feedback loops function as monotone systems that display well-ordered behavior. Perturbations to monotone systems have unambiguous global effects and a predictability characteristic that confers advantages for robustness and adaptability. We find that three intracellular regulatory networks: bacterial and yeast transcriptional networks and a mammalian signaling network contain far more sign-consistent feedback and feed-forward loops than expected for shuffled networks. Inconsistent loops with negative links can be more easily removed from real regulatory networks as compared to shuffled networks. This topological feature in real networks emerges from the presence of hubs that are enriched for either negative or positive links, and is not due to a preference for double negative links in paths. These observations indicate that intracellular regulatory networks may be close to monotone systems and that this network topology contributes to the dynamic stability.
Highlights
Three meso-scale (100-1,000 nodes) intracellular regulatory networks that specify the directionality and the effects of interactions have been developed: a mammalian cell signaling biochemical regulatory network in neurons [1], a bacterial (Escherichia Coli) gene regulatory network [2, 3], and a yeast (Saccharomyces cerevisiae) gene regulatory network [4, 5]
In this study we address the question of whether intracellular biological regulatory networks are close to monotone systems by analyzing three sign-specified directed networks
Our study demonstrates that intracellular biological regulatory networks may be close to monotone systems due to selection for positive feedback and feed-forward loops and selection against negative feedback and feed-forward loops
Summary
Three meso-scale (100-1,000 nodes) intracellular regulatory networks that specify the directionality and the effects of interactions have been developed: a mammalian cell signaling biochemical regulatory network in neurons [1], a bacterial (Escherichia Coli) gene regulatory network [2, 3], and a yeast (Saccharomyces cerevisiae) gene regulatory network [4, 5]. Extensively studied in control theory, are mathematically guaranteed to evolve in a predictable manner They do not exhibit observable chaotic behavior, while variable quantitative levels generically approach steady states as a function of time [9,10,11,12]. Bi-stability, multi-stability and monotone dynamics are typical in cell signaling regulatory networks and transcription quantitative levels in gene regulatory networks [13,14,15,16]
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