Maintenance of heme homeostasis in Staphylococcus aureus through post-translational regulation of glutamyl-tRNA reductase.

Staphylococcus aureus is an important human pathogen responsible for a variety of infections including skin and soft tissue infections, endocarditis, and sepsis. The combination of increasing antibiotic resistance in this pathogen and the lack of an efficacious vaccine underscores the importance of understanding how S. aureus maintains metabolic homeostasis in a variety of environments, particularly during infection. Within the host, S. aureus must regulate cellular levels of the cofactor heme to support enzymatic activities without encountering heme toxicity. Glutamyl tRNA reductase (GtrR), the enzyme catalyzing the first committed step in heme synthesis, is an important regulatory node of heme synthesis in Bacteria, Archaea, and Plantae. In many organisms, heme status negatively regulates the abundance of GtrR, controlling flux through the heme synthesis pathway. We identified two residues within GtrR, H32 and R214, that are important for GtrR-heme binding. However, in strains expressing either GtrRH32A or GtrRR214A, heme homeostasis was not perturbed, suggesting an alternative mechanism of heme synthesis regulation occurs in S. aureus. In this regard, we report that heme synthesis is regulated through phosphorylation and dephosphorylation of GtrR by the serine/threonine kinase Stk1 and the phosphatase Stp1, respectively. Taken together, these results suggest that the mechanisms governing staphylococcal heme synthesis integrate both the availability of heme and the growth status of the cell. IMPORTANCE Staphylococcus aureus represents a significant threat to human health. Heme is an iron-containing enzymatic cofactor that can be toxic at elevated levels. During infection, S. aureus must control heme levels to replicate and survive within the hostile host environment. We identified residues within a heme biosynthetic enzyme that are critical for heme binding in vitro; however, abrogation of heme binding is not sufficient to perturb heme homeostasis within S. aureus. This marks a divergence from previously reported mechanisms of heme-dependent regulation of the highly conserved enzyme glutamyl tRNA reductase (GtrR). Additionally, we link cell growth arrest to the modulation of heme levels through the post-translational regulation of GtrR by the kinase Stk1 and the phosphatase Stp1.

DnaJ and ClpX Are Required for HitRS and HssRS Two-Component System Signaling in Bacillus anthracis.

Bacillus anthracis is the causative agent of anthrax. This Gram-positive bacterium poses a substantial risk to human health due to high mortality rates and the potential for malicious use as a bioterror weapon. To survive within the vertebrate host, B. anthracis relies on two-component system (TCS) signaling to sense host-induced stresses and respond to alterations in the environment through changes in target gene expression. HitRS and HssRS are cross-regulating TCSs in B. anthracis that respond to cell envelope disruptions and high heme levels, respectively. In this study, an unbiased and targeted genetic selection was designed to identify gene products that are involved in HitRS and HssRS signaling. This selection led to the identification of inactivating mutations within dnaJ and clpX that disrupt HitRS- and HssRS-dependent gene expression. DnaJ and ClpX are the substrate-binding subunits of the DnaJK protein chaperone and ClpXP protease, respectively. DnaJ regulates the levels of HitR and HitS to facilitate signal transduction, while ClpX specifically regulates HitS levels. Together, these results reveal that the protein homeostasis regulators, DnaJ and ClpX, function to maintain B. anthracis signal transduction activities through TCS regulation.

Functional Properties of Oligomeric and Monomeric Forms of Helicobacter pylori VacA Toxin.

Helicobacter pylori VacA is a secreted toxin that assembles into water-soluble oligomeric structures and forms anion-selective membrane channels. Acidification of purified VacA enhances its activity in cell culture assays. Sites of protomer-protomer contact within VacA oligomers have been identified by cryoelectron microscopy, and in the current study, we validated several of these interactions by chemical cross-linking and mass spectrometry. We then mutated amino acids at these contact sites and analyzed the effects of the alterations on VacA oligomerization and activity. VacA proteins with amino acid charge reversals at interprotomer contact sites retained the capacity to assemble into water-soluble oligomers and retained cell-vacuolating activity. Introduction of paired cysteine substitutions at these sites resulted in formation of disulfide bonds between adjacent protomers. Negative-stain electron microscopy and single-particle two-dimensional class analysis revealed that wild-type VacA oligomers disassemble when exposed to acidic pH, whereas the mutant proteins with paired cysteine substitutions retain an oligomeric state at acidic pH. Acid-activated wild-type VacA caused vacuolation of cultured cells, whereas acid-activated mutant proteins with paired cysteine substitutions lacked cell-vacuolating activity. Treatment of these mutant proteins with both low pH and a reducing agent resulted in VacA binding to cells, VacA internalization, and cell vacuolation. Internalization of a nonoligomerizing mutant form of VacA by host cells was detected without a requirement for acid activation. Collectively, these results enhance our understanding of the molecular interactions required for VacA oligomerization and support a model in which toxin activity depends on interactions of monomeric VacA with host cells.