Network Rewiring: Physiological Consequences of Reciprocally Exchanging the Physical Locations and Growth-Phase-Dependent Expression Patterns of the Salmonella fis and dps Genes.

Marina M Bogue,Charles J Dorman,Aalap Mogre,Michael C Beckett,Nicholas R Thomson,Kelly T Hughes

doi:10.1128/mbio.02128-20

Marina M Bogue, Charles J Dorman + Show 4 more

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https://doi.org/10.1128/mbio.02128-20

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Journal: mBio	Publication Date: Sep 8, 2020
Citations: 13	License type: CC BY 4.0

Affiliation: Trinity College Dublin, Wellcome Connecting Science

Abstract

The Fis nucleoid-associated protein controls the expression of a large and diverse regulon of genes in Gram-negative bacteria. Fis production is normally maximal in bacteria during the early exponential phase of batch culture growth, becoming almost undetectable by the onset of stationary phase. We tested the effect on the Fis regulatory network in Salmonella of moving the complete fis gene from its usual location near the origin of chromosomal replication to the position normally occupied by the dps gene in the right macrodomain of the chromosome, and vice versa, creating the gene exchange (GX) strain. In a parallel experiment, we tested the effect of rewiring the Fis regulatory network by placing the fis open reading frame under the control of the stationary-phase-activated dps promoter at the dps genetic location within the right macrodomain, and vice versa, creating the open reading frame exchange (OX) strain. Chromatin immunoprecipitation sequencing (ChIP-seq) was used to measure global Fis protein binding levels and to determine gene expression patterns. Strain GX showed few changes compared with the wild type, although we did detect increased Fis binding at Ter, accompanied by reduced binding at Ori. Strain OX displayed a more pronounced version of this distorted Fis protein-binding pattern together with numerous alterations in the expression of genes in the Fis regulon. OX, but not GX, had a reduced ability to infect cultured mammalian cells. These findings illustrate the inherent robustness of the Fis regulatory network with respect to the effects of rewiring based on gene repositioning alone and emphasize the importance of fis expression signals in phenotypic determination.IMPORTANCE We assessed the impact on Salmonella physiology of reciprocally translocating the genes encoding the Fis and Dps nucleoid-associated proteins (NAPs) and of inverting their growth-phase production patterns such that Fis was produced in stationary phase (like Dps) and Dps was produced in exponential phase (like Fis). Changes to peak binding of Fis were detected by ChIP-seq on the chromosome, as were widespread impacts on the transcriptome, especially when Fis production mimicked Dps production. Virulence gene expression and the expression of a virulence phenotype were altered. Overall, these radical changes to NAP gene expression were well tolerated, revealing the robust and well-buffered nature of global gene regulation networks in the bacterium.

Highlights

IMPORTANCE We assessed the impact on Salmonella physiology of reciprocally translocating the genes encoding the Fis and Dps nucleoid-associated proteins (NAPs) and of inverting their growth-phase production patterns such that Fis was produced in stationary phase and Dps was produced in exponential phase
We were encouraged in our investigation by a previous study in which the translocation of the dusB-fis operon to the Ter region of the E. coli chromosome correlated with changes to the topology of a reporter plasmid and stress resistance, albeit without alterations to Fis protein levels in the cell [12]
The lack of alteration in Fis protein levels was a consequence of an increase in fis expression, which compensated for the reduction in the fis gene copy number [12]

Summary

Introduction

IMPORTANCE We assessed the impact on Salmonella physiology of reciprocally translocating the genes encoding the Fis and Dps nucleoid-associated proteins (NAPs) and of inverting their growth-phase production patterns such that Fis was produced in stationary phase (like Dps) and Dps was produced in exponential phase (like Fis). Gene position correlates with gene copy number in fast-growing bacteria, when replication recommences before cell division is complete This correlation is conserved across the Gammaproteobacteria [8] suggesting that it is biologically meaningful and may have consequences for the operation of bacterial gene control networks. This hypothesis is supported by previously reported observations suggesting that gene relocations that occur naturally, e.g., through inversions of chromosomal segments, tend to preserve the distance of the affected gene(s) from oriC [9,10,11]. The association of high Fis concentrations with the early exponential (EE) phase of growth is thought to be indicative of a role for Fis in signaling growth-cycle-related information to the global gene expression program of the cell [31, 35, 36]

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