Paper

Phys. Chem. Chem. Phys., 2009, 11, 4861 - 4870, DOI: 10.1039/b900335p

---

Stochastic bifurcation, slow fluctuations, and bistability as an origin of biochemical complexity

Hong Qian, Pei-Zhe Shi and Jianhua Xing

---

We present a simple, unifying theory for stochastic biochemical systems with multiple time-scale dynamics that exhibit noise-induced bistability in an open-chemical environment, while the corresponding macroscopic reaction is unistable. Nonlinear stochastic biochemical systems like these are fundamentally different from classical systems in equilibrium or near-equilibrium steady state whose fluctuations are unimodal following Einstein–Onsager–Lax–Keizer theory. We show that noise-induced bistability in general arises from slow fluctuations, and a pitchfork bifurcation occurs as the rate of fluctuations decreases. Since an equilibrium distribution, due to detailed balance, has to be independent of changes in time-scale, the bifurcation is necessarily a driven phenomenon. As examples, we analyze three biochemical networks of currently interest: self-regulating gene, stochastic binary decision, and phosphorylation-dephosphorylation cycle with fluctuating kinase. The implications of bistability to biochemical complexity are discussed.

About this Journal

• Journal Home
• About the Journal

Read the Journal

• Advance Articles
• Browse Issues
• Search RSC Journals
• RSC Prospect Structure Search
• E-Alerts Service
• RSS feed

ReSourCe

• Submit an Article
• Author Guidelines
• Ethical Guidelines
• Copyright & Permissions
• Referee Report Forms

Explore the Journal

• Hot Articles
• Cover Gallery
• Top 10
• People and Contacts

Customer Services

• Subscriptions
• Advertising
• Librarians

Tools