Abstract
Virulence of pathogenic bacteria is often determined by their ability to adapt to stress. The Brucella abortus general stress response (GSR) system is required for chronic mammalian infection and is regulated by phosphorylation and proteolysis. The B. abortus GSR signaling pathway has multiple layers of post-translational control and is a determinant of chronic infection. This study provides new, molecular level insight into chronic Brucella infection. Brucella spp. are adept at establishing a chronic infection in mammals. We demonstrate that core components of the α-proteobacterial general stress response (GSR) system, PhyR and σ(E1), are required for Brucella abortus stress survival in vitro and maintenance of chronic murine infection in vivo. ΔphyR and ΔrpoE1 null mutants exhibit decreased survival under acute oxidative and acid stress but are not defective in infection of primary murine macrophages or in initial colonization of BALB/c mouse spleens. However, ΔphyR and ΔrpoE1 mutants are attenuated in spleens beginning 1 month postinfection. Thus, the B. abortus GSR system is dispensable for colonization but is required to maintain chronic infection. A genome-scale analysis of the B. abortus GSR regulon identified stress response genes previously linked to virulence and genes that affect immunomodulatory components of the cell envelope. These data support a model in which the GSR system affects both stress survival and the interface between B. abortus and the host immune system. We further demonstrate that PhyR proteolysis is a unique feature of GSR control in B. abortus. Proteolysis of PhyR provides a mechanism to avoid spurious PhyR protein interactions that inappropriately activate GSR-dependent transcription. We conclude that the B. abortus GSR system regulates acute stress adaptation and long term survival within a mammalian host and that PhyR proteolysis is a novel regulatory feature in B. abortus that ensures proper control of GSR transcription.
Highlights
Virulence of pathogenic bacteria is often determined by their ability to adapt to stress
We demonstrate that core components of the ␣-proteobacterial general stress response (GSR) system, PhyR and E1, are required for Brucella abortus stress survival in vitro and maintenance of chronic murine infection in vivo. ⌬phyR and ⌬rpoE1 null mutants exhibit decreased survival under acute oxidative and acid stress but are not defective in infection of primary murine macrophages or in initial colonization of BALB/c mouse spleens
The phyR-nepR-rpoE1 Locus Determines B. abortus Survival during Oxidative and Acid Stress—To test the role of the predicted phyR-nepR-rpoE1 GSR in B. abortus 2308 stress survival, we first measured differences in cell viability between wild-type strain 2308 and single and double in-frame deletion strains of phyR, nepR, and rpoE1 that were grown to early stationary phase and subjected to equivalent levels of oxidative or acid stress
Summary
Virulence of pathogenic bacteria is often determined by their ability to adapt to stress. Results: The Brucella abortus general stress response (GSR) system is required for chronic mammalian infection and is regulated by phosphorylation and proteolysis. We demonstrate that core components of the ␣-proteobacterial general stress response (GSR) system, PhyR and E1, are required for Brucella abortus stress survival in vitro and maintenance of chronic murine infection in vivo. We present a genetic and molecular analysis of the Brucella abortus general stress response (GSR) system, which integrates features of two-component signal transduction and extracytoplasmic function (ECF)2 transcriptional regulation [10, 11]. We report that the B. abortus 2308 phyR-nepR-rpoE1 system is required for survival under acute oxidative and acid stress in vitro and for maintenance of B. abortus within murine spleens during the chronic phase of infection (i.e. Ͼ1 month postinfection). Diversity in GSR regulation probably reflects the broad range of ecological niches inhabited by ␣-proteobacterial species, from dilute freshwater to plant surfaces to mammalian phagocytic cells
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