Metal homeostasis in bacterial cells is a highly regulated process requiring intricately coordinated import and export, as well as precise sensing of intracellular metal concentrations. The uptake of zinc (Zn) has been linked to the virulence of Brucella abortus; however, the capacity of Brucella strains to sense Zn levels and subsequently coordinate Zn homeostasis has not been described. Here, we show that expression of the genes encoding the zinc uptake system ZnuABC is negatively regulated by the Znsensing Fur family transcriptional regulator, Zur, by direct interactions between Zur and the promoter region of znuABC. Moreover, the MerR-type regulator, ZntR, controls the expression of the gene encoding the Zn exporter ZntA by binding directly to its promoter. Deletion of zur or zntR alone did not result in increased zinc toxicity in the corresponding mutants; however, deletion of zntA led to increased sensitivity to Zn but not to other metals, such as Cu and Ni, suggesting that ZntA is a Zn-specific exporter. Strikingly, deletion of zntR resulted in significant attenuation of B. abortus in a mouse model of chronic infection, and subsequent experiments revealed that overexpression of zntA in the zntR mutant is the molecular basis for its decreased virulence.
IMPORTANCEThe importance of zinc uptake for Brucella pathogenesis has been demonstrated previously, but to date, there has been no description of how overall zinc homeostasis is maintained and genetically controlled in the brucellae. The present work defines the predominant zinc export system, as well as the key genetic regulators of both zinc uptake and export in Brucella abortus. Moreover, the data show the importance of precise coordination of the zinc homeostasis systems as disregulation of some elements of these systems leads to the attenuation of Brucella virulence in a mouse model. Overall, this study advances our understanding of the essential role of zinc in the pathogenesis of intracellular bacteria.T he pathogenic alphaproteobacterium Brucella abortus preferentially infects cattle, bison, and elk (1), but the bacteria are also highly efficient at infecting humans. In order to establish a chronic infection in these hosts, the brucellae must survive and replicate within host macrophages (2). While the macrophage serves as the niche for Brucella during a chronic infection, the intracellular environment of these phagocytic immune cells is inhospitable as the bacteria are bombarded with a variety of environmental stresses, including exposure to reactive oxygen species (ROS), low pH, limited oxygen availability, and nutrient deprivation (3). Notwithstanding, the brucellae have evolved multiple strategies to cope with the harsh intramacrophagic environment and ultimately establish a replicative niche in these cells.With regard to the nutrient limitation experienced by the brucellae within macrophages, metal cations are likely found in extremely low concentrations, and, in fact, macrophages produce transporters, such as the NRAMP family of transp...
