Abstract

In the presence of oxygen (O2) the model bacterium Escherichia coli is able to conserve energy by aerobic respiration. Two major terminal oxidases are involved in this process - Cyo has a relatively low affinity for O2 but is able to pump protons and hence is energetically efficient; Cyd has a high affinity for O2 but does not pump protons. When E. coli encounters environments with different O2 availabilities, the expression of the genes encoding the alternative terminal oxidases, the cydAB and cyoABCDE operons, are regulated by two O2-responsive transcription factors, ArcA (an indirect O2 sensor) and FNR (a direct O2 sensor). It has been suggested that O2-consumption by the terminal oxidases located at the cytoplasmic membrane significantly affects the activities of ArcA and FNR in the bacterial nucleoid. In this study, an agent-based modeling approach has been taken to spatially simulate the uptake and consumption of O2 by E. coli and the consequent modulation of ArcA and FNR activities based on experimental data obtained from highly controlled chemostat cultures. The molecules of O2, transcription factors and terminal oxidases are treated as individual agents and their behaviors and interactions are imitated in a simulated 3-D E. coli cell. The model implies that there are two barriers that dampen the response of FNR to O2, i.e. consumption of O2 at the membrane by the terminal oxidases and reaction of O2 with cytoplasmic FNR. Analysis of FNR variants suggested that the monomer-dimer transition is the key step in FNR-mediated repression of gene expression.

Highlights

  • The bacterium Escherichia coli is a widely used model organism to study bacterial adaptation to environmental change

  • In order to exploit the energetic benefits that are conferred by aerobic respiration, E. coli has two major terminal oxidases: cytochrome bd-I (Cyd) and cytochrome bo9 (Cyo) that are encoded by the cydAB and cyoABCDE operons, respectively [1,2]

  • FNR acts as a global regulator in E. coli [11,12,13], including the cydAB and cyoABCDE operons, which are repressed by FNR when the O2 supply is restricted [7]

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Summary

Introduction

The bacterium Escherichia coli is a widely used model organism to study bacterial adaptation to environmental change. Phosphorylated ArcB is able to transfer phosphate to the cytoplasmic ArcA regulator (ArcA,P), which undergoes oligomerization to form a tetra-phosphorylated octomer that is capable of binding at multiple sites in the E. coli genome [17,18], including those in the promoter regions of cydAB and cyoABCDE to enhance synthesis of Cyd and inhibit production of Cyo [7,17]. Because the terminal oxidases (Cyd and Cyo) consume O2 at the cell membrane, a feedback loop is formed that links the activities of the oxidases to the regulatory activities of ArcA and FNR (Figure 1). These features of the system - Author Summary

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