ABSTRACT
MsrPQ is a newly identified methionine sulfoxide reductase system found in bacteria, which appears to be specifically involved in the repair of periplasmic proteins oxidized by hypochlorous acid. It involves two proteins: a periplasmic one, MsrP, previously named YedY, carrying out the Msr activity, and MsrQ, an integral b-type heme membrane-spanning protein, which acts as the specific electron donor to MsrP. MsrQ, previously named YedZ, was mainly characterized by bioinformatics as a member of the FRD superfamily of heme-containing membrane proteins, which include the NADPH oxidase proteins (NOX/DUOX). Here we report a detailed biochemical characterization of the MsrQ protein from Escherichia coli We optimized conditions for the overexpression and membrane solubilization of an MsrQ-GFP fusion and set up a purification scheme allowing the production of pure MsrQ. Combining UV-visible spectroscopy, heme quantification, and site-directed mutagenesis of histidine residues, we demonstrated that MsrQ is able to bind two b-type hemes through the histidine residues conserved between the MsrQ and NOX protein families. In addition, we identify the E. coli flavin reductase Fre, which is related to the dehydrogenase domain of eukaryotic NOX enzymes, as an efficient cytosolic electron donor to the MsrQ heme moieties. Cross-linking experiments as well as surface Plasmon resonance showed that Fre interacts with MsrQ to form a specific complex. Taken together, these data support the identification of the first prokaryotic two-component protein system related to the eukaryotic NOX family and involved in the reduction of periplasmic oxidized proteins.
Subject(s)
Escherichia coli/enzymology , Methionine Sulfoxide Reductases/metabolism , NADPH Oxidases/metabolism , Amino Acid Sequence , Electron Transport , Green Fluorescent Proteins/genetics , Methionine Sulfoxide Reductases/chemistry , Methionine Sulfoxide Reductases/genetics , Mutagenesis, Site-Directed , Sequence Homology, Amino Acid , Spectrophotometry, Ultraviolet , Surface Plasmon ResonanceABSTRACT
PerR is the peroxide resistance regulator found in several pathogenic bacteria and governs their resistance to peroxide stress by inducing enzymes that destroy peroxides. However, it has recently been implicated as a key component of the aerotolerance in several facultative or strict anaerobes, including the highly pathogenic Staphylococcus aureus. By combining (18)O labeling studies to ESI- and MALDI-TOF MS detection and EMSA experiments, we demonstrate that the active form of PerR reacts with dioxygen, which leads ultimately to disruption of the PerR/DNA complex and is thus physiologically meaningful. Moreover, we show that the presence of O2 assists PerR sensing of H2O2, another feature likely to be important for anaerobic organisms. These results allow one to envisage different scenarios for the response of anaerobes to air exposure.
Subject(s)
Bacillus subtilis/metabolism , Bacteria, Anaerobic/metabolism , Bacterial Proteins/metabolism , Hydrogen Peroxide/metabolism , Oxygen/metabolism , Repressor Proteins/metabolism , DNA, Bacterial/metabolism , Oxidation-Reduction , Staphylococcus aureus/metabolismABSTRACT
Fur family proteins, ubiquitous in prokaryotes, play a pivotal role in microbial survival and virulence in most pathogens. Metalloregulators, such as Fur and PerR, regulate the transcription of genes connected to iron homeostasis and response to oxidative stress, respectively. In Bacillus subtilis, Fur and PerR bind with high affinity to DNA sequences differing at only two nucleotides. In addition to these differences in the PerR and Fur boxes, we identify in this study a residue located on the DNA binding motif of the Fur protein that is critical to discrimination between the two close DNA sequences. Interestingly, when this residue is introduced into PerR, it lowers the affinity of PerR for its own DNA target but confers to the protein the ability to interact strongly with the Fur DNA binding sequence. The present data show how two closely related proteins have distinct biological properties just by changing a single residue.
Subject(s)
Bacillus subtilis/genetics , Bacterial Proteins/genetics , DNA, Bacterial/chemistry , Gene Expression Regulation, Bacterial , Mutation , Repressor Proteins/genetics , Arginine/metabolism , Asparagine/metabolism , Bacillus subtilis/metabolism , Bacterial Proteins/chemistry , Bacterial Proteins/metabolism , Base Sequence , DNA, Bacterial/genetics , DNA, Bacterial/metabolism , Molecular Sequence Data , Protein Binding , Protein Interaction Domains and Motifs , Repressor Proteins/chemistry , Repressor Proteins/metabolism , Transcription, GeneticSubject(s)
Bacteria/metabolism , Bacterial Proteins/metabolism , Hydrogen Peroxide/metabolism , Repressor Proteins/metabolism , Amino Acid Sequence , Aspartic Acid/chemistry , Aspartic Acid/genetics , Aspartic Acid/metabolism , Bacteria/chemistry , Bacteria/genetics , Bacterial Proteins/chemistry , Bacterial Proteins/genetics , Glutamic Acid/chemistry , Glutamic Acid/genetics , Glutamic Acid/metabolism , Humans , Models, Molecular , Molecular Sequence Data , Point Mutation , Repressor Proteins/chemistry , Repressor Proteins/genetics , Sequence Alignment , Spectroscopy, MossbauerABSTRACT
In Bacillus subtilis, PerR is a metal-dependent sensor of hydrogen peroxide. PerR is a dimeric zinc protein with a regulatory site that coordinates either Fe(2+) (PerR-Zn-Fe) or Mn(2+) (PerR-Zn-Mn). Though most of the peroxide sensors use cysteines to detect H(2)O(2), it has been shown that reaction of PerR-Zn-Fe with H(2)O(2) leads to the oxidation of one histidine residue. Oxidation of PerR leads to the incorporation of one oxygen atom into His37 or His91. This study presents the crystal structure of the oxidized PerR protein (PerR-Zn-ox), which clearly shows a 2-oxo-histidine residue in position 37. Formation of 2-oxo-histidine is demonstrated and quantified by HPLC-MS/MS. EPR experiments indicate that PerR-Zn-H37ox retains a significant affinity for the regulatory metal, whereas PerR-Zn-H91ox shows a considerably reduced affinity for the metal ion. In spite of these major differences in terms of metal binding affinity, oxidation of His37 and/or His91 in PerR prevents DNA binding.
Subject(s)
Bacterial Proteins/chemistry , Bacterial Proteins/metabolism , Histidine/chemistry , Histidine/metabolism , Repressor Proteins/chemistry , Repressor Proteins/metabolism , Bacillus subtilis/metabolism , DNA, Bacterial/chemistry , Gene Expression Regulation, Bacterial/physiology , Mass Spectrometry , Models, Molecular , Oxidation-Reduction , Protein Binding , Protein ConformationABSTRACT
Fur is a bacterial regulator using iron as a cofactor to bind to specific DNA sequences. This protein exists in solution as several oligomeric states, of which the dimer is generally assumed to be the biologically relevant one. We describe the equilibria that exist between dimeric Escherichia coli Fur and higher oligomers. The dissociation constant for the dimer-tetramer equilibrium is estimated to be in the millimolar range. Oligomerization is enhanced at low ionic strength and pH. The as-isolated monomeric form of Fur is not in equilibrium with the dimer and contains two disulfide bridges (C92-C95 and C132-C137). Binding of the monomer to DNA is metal-dependent and sequence specific with an apparent affinity 5.5 times lower than that of the dimer. Size exclusion chromatography, EDC cross-linking, and CD spectroscopy show that reconstitution of the dimer from the monomer requires reduction of the disulfide bridges and coordination of Zn2+. Reduction of the disulfide bridges or Zn2+ alone does not promote dimerization. EDC and DMA cross-links reveal that the N-terminal NH2 group of one subunit is in an ionic interaction with acidic residues of the C-terminal tail and close to Lys76 and Lys97 of the other. Furthermore, the yields of cross-link drastically decrease upon binding of metal in the activation site, suggesting that the N-terminus is involved in the conformational change. Conversely, oxidizing reagents, H2O2 or diamide, disrupt the dimeric structure leading to monomer formation. These results establish that coordination of the zinc ion and the redox state of the cysteines are essential for holding E. coli Fur in a dimeric state.
Subject(s)
Bacterial Proteins/chemistry , Escherichia coli Proteins/chemistry , Repressor Proteins/chemistry , Zinc/chemistry , Circular Dichroism , Cross-Linking Reagents , Dimerization , Disulfides , Oxidation-Reduction , Protein Conformation , Spectrometry, Mass, Matrix-Assisted Laser Desorption-IonizationABSTRACT
Bacteria adapt to elevated levels of Reactive Oxygen Species (ROS) by increasing the expression of defence and repair proteins, which is regulated by ROS responsive transcription factors. In Bacillus subtilis the zinc protein PerR, a peroxide sensor that binds DNA in the presence of a regulatory metal Mn2+ or Fe2+, mediates the adaptive response to H2O2. This study presents the first crystal structure of apo-PerR-Zn which shows that all four cysteine residues of the protein are involved in zinc co-ordination. The Zn(Cys)4 site locks the dimerization domain and stabilizes the dimer. Sequence alignment of PerR-like proteins supports that this structural site may constitute a distinctive feature of this class of peroxide stress regulators.