An oxidation-sensing mechanism is used by the global regulator MgrA in Staphylococcus aureus

Staphylococcus aureus is a human pathogen responsible for most wound and hospital-acquired infections. The protein MgrA is both an important virulence determinant during infection and a regulator of antibiotic resistance in S. aureus. The crystal structure of the MgrA homodimer, solved at 2.86 A, indicates the presence of a unique cysteine residue located at the interface of the protein dimer. We discovered that this cysteine residue can be oxidized by various reactive oxygen species, such as hydrogen peroxide and organic hydroperoxide. Cysteine oxidation leads to dissociation of MgrA from DNA and initiation of signaling pathways that turn on antibiotic resistance in S. aureus. The oxidation-sensing mechanism is typically used by bacteria to counter challenges of reactive oxygen and nitrogen species. Our study reveals that in S. aureus, MgrA adopts a similar mechanism but uses it to globally regulate different defensive pathways.     

mgrA regulates staphylococcal virulence important for induction and progression of septic arthritis and sepsis

Septic arthritis and sepsis are common and feared complications of staphylococcal infections, and the increasing antibiotic resistance among staphylococci urge the extended research for virulence factors involved in these diseases. Staphylcoccus aureus produces a number of virulence factors controlled by several global regulatory genes including agr and sarA. MgrA is a recently identified global regulator, belonging to the SarA subfamily, which upregulates expression of several virulence factors including capsule and sortase. In addition, MgrA has been shown to regulate antibiotic resistance and decrease bacterial autolysis. In this study we have assessed the role of mgrA gene expression on induction and progression of septic arthritis and sepsis. Mice inoculated with the mgrA mutant displayed significantly less severe arthritis and showed a significantly better weight development, than wild-type inoculated mice. Importantly, all 10 mice inoculated with the mgrA mutant survived as compared to 70% mortality in the wild-type inoculated mice (p=0.003). In addition, the mgrA mutant showed significantly less bacterial persistence in kidneys as compared to the wild-type strain. We conclude that mgrA regulates virulence factors important for establishment and progression of septic arthritis and sepsis.     

Staphylococcus aureus CymR is a new thiol-based oxidation-sensing regulator of stress resistance and oxidative response

As a human pathogen, Staphylococcus aureus must cope with oxidative stress generated by the human immune system. Here, we report that CymR utilizes its sole Cys-25 to sense oxidative stress. Oxidation followed by thiolation of this cysteine residue leads to dissociation of CymR from its cognate promoter DNA. In contrast, the DNA binding of the CymRC25S mutant was insensitive to oxidation and thiolation, suggesting that CymR senses oxidative stress through oxidation of its sole cysteine to form a mixed disulfide with low molecular weight thiols. The determined crystal structures of the reduced and oxidized forms of CymR revealed that Cys-25 is oxidized to Cys-25-SOH in the presence of H(2)O(2). Deletion of cymR reduced the resistance of S. aureus to oxidative stresses, and the resistance was restored by expressing a C25S mutant copy of cymR. In a C25S substitution mutant, the expression of two genes, tcyP and mccB, was constitutively repressed and did not respond to hydrogen peroxide stress, whereas the expression of the genes were highly induced under oxidative stress in a wild-type strain, indicating the critical role of Cys-25 in redox signaling in vivo. Thus, CymR is another master regulator that senses oxidative stress and connects stress responses to virulence regulation in S. aureus.     

金黄色葡萄球菌附属基因调节系统研究进展

金黄色葡萄球菌的微生物病原特性非常复杂并且不断地产生抗生素抗性,目前迫切需要增加对金黄色葡萄球菌的了解。它所引起的疾病与大量毒力因子相关,这些毒力因子的表达是受多个基因调控,其中agr（accessory gene regulator,附属基因调节）是最主要的一个。由于agr系统与人类的多种疾病有关,研究的较为深入,现已成为一个理解群体感应激活和抑制机制的模型系统。agr系统以及其它菌的群体感应系统已经引起了越来越多研究者的注意,本文对agr系统的研究现状、研究过程中发现的问题及其潜在应用价值作了深入地探讨。     

The Staphylococcus aureus ArlRS two-component system regulates virulence factor expression through MgrA

The Gram-positive bacterium, Staphylococcus aureus, is a versatile pathogen that can sense and adapt to a wide variety of environments within the human host, in part through its 16 two-component regulatory systems. The ArlRS two-component system has been shown to affect many cellular processes in S. aureus, including autolysis, biofilm formation, capsule synthesis and virulence. Yet the molecular details of this regulation remained largely unknown. We used RNA sequencing to identify the ArlRS regulon, and found 70% overlap with that of the global regulator MgrA. These genes included cell wall-anchored adhesins (ebh, sdrD), polysaccharide and capsule synthesis genes, cell wall remodeling genes (lytN, ddh), the urease operon, genes involved in metal transport (feoA, mntH, sirA), anaerobic metabolism genes (adhE, pflA, nrdDG) and a large number of virulence factors (lukSF, lukAB, nuc, gehB, norB, chs, scn and esxA). We show that ArlR directly activates expression of mgrA and identify a probable ArlR-binding site (TTTTCTCAT-N₄-TTTTAATAA). A highly similar sequence is also found in the spx P2 promoter, which was recently shown to be regulated by ArlRS. We also demonstrate that ArlS has kinase activity toward ArlR in vitro, although it has slower kinetics than other similar histidine kinases.     

The nitrosative stress response of Staphylococcus aureus is required for resistance to innate immunity

Staphylococcus aureus is a highly virulent human pathogen with an extensive array of strategies to subvert the innate immune response. An important aspect of innate immunity is the production of the nitrogen monoxide radical (Nitric Oxide, NO.). Here we describe an adaptive response to nitrosative stress that allows S. aureus to replicate at high concentrations of NO.. Microarray analysis revealed 84 staphylococcal genes with significantly altered expression following NO. exposure. Of these, 30 are involved with iron-homeostasis, potentially under the control of the Fur regulator. Another seven induced genes are involved in hypoxic/fermentative metabolism, including the flavohaemoprotein, Hmp. The SrrAB two-component system has been shown to regulate the expression of many of the NO.-induced metabolic genes. Indeed, inactivation of hmp, srrAB and fur resulted in heightened NO. sensitivity. Hmp was responsible for c. 90% of measurable staphylococcal NO. consumption and therefore critical for efficient NO. detoxification. While SrrAB was required for maximal hmp expression, srrAB mutants still exhibited significant NO. scavenging and NO.-dependent induction of hmp. Yet S. aureus lacking SrrAB were more sensitive to nitrosative stress than hmp mutants, indicating that the contribution of SrrAB to NO. resistance extends beyond the regulation of hmp expression. Both Hmp and SrrAB were required for full virulence in a murine sepsis model, however, only the attenuation of the hmp mutant was restored by the abrogation of host NO. production. Thus, the S. aureus Hmp protein has evolved to serve as an iNOS-dependent virulence determinant.     

Pseudomonas aeruginosa OspR is an oxidative stress sensing regulator that affects pigment production, antibiotic resistance and dissemination during infection

Oxidative stress is one of the main challenges bacteria must cope with during infection. Here, we identify a new oxidative stress sensing and response ospR ( o xidative s tress response and p igment production R egulator) gene in Pseudomonas aeruginosa . Deletion of ospR leads to a significant induction in H₂O₂ resistance. This effect is mediated by de-repression of PA2826 , which lies immediately upstream of ospR and encodes a glutathione peroxidase. Constitutive expression of ospR alters pigment production and β-lactam resistance in P. aeruginosa via a PA2826 -independent manner. We further discovered that OspR regulates additional genes involved in quorum sensing and tyrosine metabolism. These regulatory effects are redox-mediated as addition of H₂O₂ or cumene hydroperoxide leads to the dissociation of OspR from promoter DNA. A conserved Cys residue, Cys-24, plays the major role of oxidative stress sensing in OspR. The serine substitution mutant of Cys-24 is less susceptible to oxidation in vitro and exhibits altered pigmentation and β-lactam resistance . Lastly, we show that an ospR null mutant strain displays a greater capacity for dissemination than wild-type MPAO1 strain in a murine model of acute pneumonia. Thus, OspR is a global regulator that senses oxidative stress and regulates multiple pathways to enhance the survival of P. aeruginosa inside host.