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Abstract

The lac operon in Escherichia coli has been studied extensively and is one of the earliest gene systems found to undergo both positive and negative control. The lac operon is known to exhibit bistability, in the sense that the operon is either induced or uninduced. Many dynamical models have been proposed to capture this phenomenon. While most are based on complex mathematical formulations, it has been suggested that for other gene systems network topology is sufficient to produce the desired dynamical behavior. We present a Boolean network as a discrete model for the lac operon. Our model includes the two main glucose control mechanisms of catabolite repression and inducer exclusion. We show that this Boolean model is capable of predicting the ON and OFF steady states and bistability. Further, we present a reduced model which shows that lac mRNA and lactose form the core of the lac operon, and that this reduced model exhibits the same dynamics. This work suggests that the key to model qualitative dynamics of gene systems is the topology of the network and Boolean models are well suited for this purpose. Supplementary Material is available online at www.libertonline.com/cmb.

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References

Aguda

, Goryachev

2007. From pathways databases to network models of switching behavior. PLoS Comput. Biol., 3:1674–1678.

Albert

, Othmer

2003. The topology of the regulatory interactions predicts the expression pattern of the segment polarity genes in Drosophila melanogaster. J. Theor. Biol., 223:1–18.

Davidich

, Bornholdt

2008. The transition from differential equations to Boolean networks: A case study in simplifying a regulatory network model. J. Theor. Biol., 25:269–277.

Gianchandani

, Papin

, Price

et al. 2006. Matrix formalism to describe functional states of transcriptional regulatory systems. PLoS Comput. Biol., 2:902–0917.

Goodwin

1963. Temporal Organization in Cells. Academic Press: New York.

Griffiths

, Miller

, Suzuki

et al. 1999. Introduction to Genetic Analysis. W.H. Freeman: New York.

Halász

, Kumar

, Imieliński

et al. 2007. Analysis of lactose metabolism in E. coli using reachability analysis of hybrid systems. IET Systems Biol., 1:130–148.

Jacob

, Monod

1961. Genetic regulatory mechanisms in the synthesis of proteins. J. Mol. Biol., 3:318–356.

Jarrah

, Laubenbacher

, Stigler

et al. 2004. DVD: Discrete Visualizer of Dynamics. http://dvd.vbi.vt.edu. 2011 March 1.

10.

Jarrah

, Laubenbacher

, Veliz-Cuba

2010. The dynamics of conjunctive and disjunctive Boolean network models. Bull. Math. Bio., 72:1425–1447.

11.

Mayo

, Setty

, Shavit

et al. 2006. Plasticity of the cis-regulatory input function of a gene. PLoS Biol., 4:555–561.

12.

Mendoza

, Xenarios

2006. A method for the generation of standardized qualitative dynamical systems of regulatory networks. Theor. Biol. Med. Model., 3:1–18.

13.

Novick

, Weiner

1957. Enzyme induction as an all-or-none phenomenon. Proc. Nat. Acad. Sci. USA, 43:553–566.

14.

Ozbudak

, Thattai

, Lim

et al. 2004. Multistability in the lactose utilization network of Escherichia coli. Nature, 427:737–740.

15.

Santillán

2008. Bistable behavior in a model of the lac operon in Escherichia coli with variable growth rate. Biophys. J., 94:2065–2081.

16.

Santillán

, Mackey

2004. Influence of catabolite repression and inducer exclusion on the bistable behavior of the lac operon. Biophys. J., 86:1282–1292.

17.

Santillán

, Mackey

, Zeron

2007. Origin of bistability in the lac operon. Biophys. J., 92:3830–3842.

18.

Setty

, Mayo

, Surette

et al. 2003. Detailed map of a cis-regulatory input function. Proc. Natl. Acad. Sci. USA, 100:7702–7707.

19.

Sontag

, Veliz-Cuba

, Laubenbacher

et al. 2008. The effect of negative feedback loops on the dynamics of Boolean networks. Biophys. J., 95:518–526.

20.

Thomas

, Thieffry

, Kaufman

1995. Dynamical behaviour of biological regulatory networks—I. Biological role of feedback loops and practical use of the concept of the loop-characteristic state. Bull. Math. Biol., 57:247–276.

21.

van Hoek

, Hogeweg

2006. In silico evolved lac operons exhibit bistability for artificial inducers, but not for lactose. Biophys. J., 91:2833–2843.

22.

van Hoek

, Hogeweg

2007. The effect of stochasticity on the lac operon: an evolutionary perspective. PLoS Comput. Biol., 3:1071–1082.

23.

Wong

, Gladney

, Keasling

1997. Mathematical model of the lac operon: inducer exclusion, catabolite repression, and diauxic growth on glucose and lactose. Biotechnol. Prog., 13:132–143.

24.

Yildirim

, Santillán

, Horike

et al. 2004. Dynamics and bistability in a reduced model of the lac operon. Chaos, 14:279–292.

Supplementary Material

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Boolean Models Can Explain Bistability in the lac Operon

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