EURASIP Journal on Bioinformatics and Systems Biology - Special issue on network structure and biological function: Reconstruction, modelling, and statistical approaches
Graphical methods for analysing feedback in biological networks-A survey
International Journal of Systems Science - Dynamics Analysis of Gene Regulatory Networks
Inferring cell cycle feedback regulation from gene expression data
Journal of Biomedical Informatics
A general procedure for accurate parameter estimation in dynamic systems using new estimation errors
ANB'10 Proceedings of the 4th international conference on Algebraic and Numeric Biology
IEEE Transactions on Very Large Scale Integration (VLSI) Systems
| Hi-index | 3.84 |
Motivation: It has been widely reported that biological networks are robust against perturbations such as mutations. On the contrary, it has also been known that biological networks are often fragile against unexpected mutations. There is a growing interest in these intriguing observations and the underlying design principle that causes such robust but fragile characteristics of biological networks. For relatively small networks, a feedback loop has been considered as an important motif for realizing the robustness. It is still, however, not clear how a number of coupled feedback loops actually affect the robustness of large complex biological networks. In particular, the relationship between fragility and feedback loops has not yet been investigated till now. Results: Through extensive computational experiments, we found that networks with a larger number of positive feedback loops and a smaller number of negative feedback loops are likely to be more robust against perturbations. Moreover, we found that the nodes of a robust network subject to perturbations are mostly involved with a smaller number of feedback loops compared with the other nodes not usually subject to perturbations. This topological characteristic eventually makes the robust network fragile against unexpected mutations at the nodes not previously exposed to perturbations. Contact: ckh@kaist.ac.kr Supplementary information: Supplementary data are available at Bioinformatics online.