Noise propagation in gene regulation networks involving interlinked positive and negative feedback loops.

Hui Zhang,Yong Chen,Kumar Selvarajoo,Yueling Chen

doi:10.1371/journal.pone.0051840

Abstract

It is well known that noise is inevitable in gene regulatory networks due to the low-copy numbers of molecules and local environmental fluctuations. The prediction of noise effects is a key issue in ensuring reliable transmission of information. Interlinked positive and negative feedback loops are essential signal transduction motifs in biological networks. Positive feedback loops are generally believed to induce a switch-like behavior, whereas negative feedback loops are thought to suppress noise effects. Here, by using the signal sensitivity (susceptibility) and noise amplification to quantify noise propagation, we analyze an abstract model of the Myc/E2F/MiR-17-92 network that is composed of a coupling between the E2F/Myc positive feedback loop and the E2F/Myc/miR-17-92 negative feedback loop. The role of the feedback loop on noise effects is found to depend on the dynamic properties of the system. When the system is in monostability or bistability with high protein concentrations, noise is consistently suppressed. However, the negative feedback loop reduces this suppression ability (or improves the noise propagation) and enhances signal sensitivity. In the case of excitability, bistability, or monostability, noise is enhanced at low protein concentrations. The negative feedback loop reduces this noise enhancement as well as the signal sensitivity. In all cases, the positive feedback loop acts contrary to the negative feedback loop. We also found that increasing the time scale of the protein module or decreasing the noise autocorrelation time can enhance noise suppression; however, the systems sensitivity remains unchanged. Taken together, our results suggest that the negative/positive feedback mechanisms in coupled feedback loop dynamically buffer noise effects rather than only suppressing or amplifying the noise.

Highlights

Gene expression is a complex stochastic process involving numerous components and reaction steps
Noise levels are related to the frequency of cellular differentiation, and a noise-related motif can be adjusted based on its dynamic behavior [8]
Our results show that the role of feedback loop in sensitivity and noise amplification is related to the dynamic properties of the system

Summary

Introduction

Gene expression is a complex stochastic process involving numerous components and reaction steps. It spans several time and concentration scales, including gene transcription, translation, and chromosome remodeling. Phenotypic noise is due to low-copy-number molecules and fluctuations in the local environment [2]. A quantitative model of noise in genetic networks has been established, and the components that contribute to fluctuations have been suggested [3]. Noise has been found to play a pivotal role in phenotypic variation and cellular differentiation [4]. Fluctuations can be considered useful for balancing precision and diversity in eukaryotic gene expression [5] and for promoting non-genetic diversity to increase the survival capabilities of prokaryotic gene expression [6]. Noise levels are related to the frequency of cellular differentiation, and a noise-related motif can be adjusted based on its dynamic behavior [8]

Methods

Results

Conclusion