Multistability in the lactose utilization network of Escherichia coli

Abstract

Multistability, the capacity to achieve multiple internal states in response to a single set of external inputs, is the defining characteristic of a switch. Biological switches are essential for the determination of cell fate in multicellular organisms¹, the regulation of cell-cycle oscillations during mitosis^2,3 and the maintenance of epigenetic traits in microbes⁴. The multistability of several natural^1,2,3,4,5,6 and synthetic^7,8,9 systems has been attributed to positive feedback loops in their regulatory networks¹⁰. However, feedback alone does not guarantee multistability. The phase diagram of a multistable system, a concise description of internal states as key parameters are varied, reveals the conditions required to produce a functional switch^11,12. Here we present the phase diagram of the bistable lactose utilization network of Escherichia coli¹³. We use this phase diagram, coupled with a mathematical model of the network, to quantitatively investigate processes such as sugar uptake and transcriptional regulation in vivo. We then show how the hysteretic response of the wild-type system can be converted to an ultrasensitive graded response^14,15. The phase diagram thus serves as a sensitive probe of molecular interactions and as a powerful tool for rational network design.