The Role of zinc in the disulphide stress-regulated anti-sigma factor RsrA from Streptomyces coelicolor

The regulation of disulphide stress in actinomycetes such as Streptomyces coelicolor is known to involve the zinc-containing anti-sigma factor RsrA that binds and inactivates the redox-regulated sigma factor sigmaR. However, it is not known how RsrA senses disulphide stress nor what role the metal ion plays. Using in vitro assays, we show that while zinc is not required for sigmaR binding it is required for functional anti-sigma factor activity, and that it plays a critical role in modulating the reactivity of RsrA cysteine thiol groups towards oxidation. Apo-RsrA is easily oxidised and, while the Zn-bound form is relatively resistant, the metal ion is readily expelled when the protein is treated with strong oxidants such as diamide. We also show, using a combination of proteolysis and mass spectrometry, that the first critical disulphide to form in RsrA involves Cys11 and one of either Cys41 or Cys44, all previously implicated in metal binding. Circular dichroism spectroscopy was used to follow structural changes during oxidation of RsrA, which indicated that concomitant with formation of this critical disulphide bond is a major restructuring of the protein where its alpha-helical content increases. Our data demonstrate that RsrA can only bind sigmaR in the reduced state and that this state is stabilised by zinc. Redox stress induces disulphide bond formation amongst zinc-ligating residues, expelling the metal ion and stabilising a structure incapable of binding the sigma factor.     

Determinants of redox sensitivity in RsrA, a zinc-containing anti-sigma factor for regulating thiol oxidative stress response

Various environmental oxidative stresses are sensed by redox-sensitive regulators through cysteine thiol oxidation or modification. A few zinc-containing anti-sigma (ZAS) factors in actinomycetes have been reported to respond sensitively to thiol oxidation, among which RsrA from Streptomyces coelicolor is best characterized. It forms disulfide bonds upon oxidation and releases bound SigR to activate thiol oxidative stress response genes. Even though numerous ZAS proteins exist in bacteria, features that confer redox sensitivity to a subset of these have been uncharacterized. In this study, we identified seven additional redox-sensitive ZAS factors from actinomycetes. Comparison with redox-insensitive ZAS revealed characteristic sequence patterns. Domain swapping demonstrated the significance of the region K(33)FEHH(37)FEEC(41)SPC(44)LEK(47) that encompass the conserved HX(3)CX(2)C (HCC) motif. Mutational effect of each residue on diamide responsive induction of SigR target genes in vivo demonstrated that several residues, especially those that flank two cysteines (E39, E40, L45, E46), contribute to redox sensitivity. These residues are well conserved among redox-sensitive ZAS factors, and hence are proposed as redox-determinants in sensitive ZAS. H37A, C41A, C44A and F38A mutations, in contrast, compromised SigR-binding activity significantly, apparently affecting structural integrity of RsrA. The residue pattern around HCC motif could therefore serve as an indicator to predict redox-sensitive ZAS factors from sequence information.     

Regulation of mycothiol metabolism by sigma(R) and the thiol redox sensor anti-sigma factor RsrA

Mycothiol (MSH) is the major thiol in Actinobacteria and plays a role analogous to that of glutathione. The biosynthetic pathway has been established in mycobacteria and is initiated by the glycosyltransferase MshA. A key mycothiol-dependent detoxification pathway utilizes the amidase (Mca) to cleave mycothiol S-conjugates to produce GlcN-Ins and a mercapturic acid excreted from the cell. How expression of mycothiol genes is regulated in mycobacteria has been unclear so the report in this issue by Park and Roe showing that in Streptomyces coelicolor the redox controlled anti-sigma factor RsrA that binds the regulator sigma(R) controls key elements of mycothiol metabolism is a major advance. Conditions that deplete thiols are shown to induce directly expression of sigR, rsrA, mshA and mca, as well as the thioredoxin reductase-thioredoxin system, generating an autoregulatory cycle that persists until the thiol-depleting condition is alleviated. Evidence for indirect induction of mshB-D to support mycothiol biosynthesis is also presented. It was shown in vitro that mycothiol, like reduced thioredoxin and dithiothreitol, can reduce oxidized RsrA to activate its binding to sigma(R). These studies establish for the first time how mycothiol metabolism is regulated to cope with stress from thiol reactive toxins.     

Characterization of the redox activity and disulfide bond formation in apurinic/apyrimidinic endonuclease

Apurinic/apyrimidinic endonuclease (APE1) is an unusual nuclear redox factor in which the redox-active cysteines identified to date, C65 and C93, are surface inaccessible residues whose activities may be influenced by partial unfolding of APE1. To assess the role of the five remaining cysteines in APE1's redox activity, double-cysteine mutants were analyzed, excluding C65A, which is redox-inactive as a single mutant. C93A/C99A APE1 was found to be redox-inactive, whereas other double-cysteine mutants retained the same redox activity as that observed for C93A APE1. To determine whether these three cysteines, C65, C93, and C99, were sufficient for redox activity, all other cysteines were substituted with alanine, and this protein was shown to be fully redox-active. Mutants with impaired redox activity failed to stimulate cell proliferation, establishing an important role for APE1's redox activity in cell growth. Disulfide bond formation upon oxidation of APE1 was analyzed by proteolysis of the protein followed by mass spectrometry analysis. Within 5 min of exposure to hydrogen peroxide, a single disulfide bond formed between C65 and C138 followed by the formation of three additional disulfide bonds within 15 min; 10 total disulfide bonds formed within 1 h. A single mixed-disulfide bond involving C99 of APE1 was observed for the reaction of oxidized APE1 with thioredoxin (TRX). Disulfide-bonded APE1 or APE1-TRX species were further characterized by size exclusion chromatography and found to form large complexes. Taken together, our data suggest that APE1 is a unique redox factor with properties distinct from those of other redox factors.     

Selective Sensitization of Zinc Finger Protein Oxidation by Reactive Oxygen Species through Arsenic Binding

Cysteine oxidation induced by reactive oxygen species (ROS) on redox-sensitive targets such as zinc finger proteins plays a critical role in redox signaling and subsequent biological outcomes. We found that arsenic exposure led to oxidation of certain zinc finger proteins based on arsenic interaction with zinc finger motifs. Analysis of zinc finger proteins isolated from arsenic-exposed cells and zinc finger peptides by mass spectrometry demonstrated preferential oxidation of C3H1 and C4 zinc finger configurations. C2H2 zinc finger proteins that do not bind arsenic were not oxidized by arsenic-generated ROS in the cellular environment. The findings suggest that selectivity in arsenic binding to zinc fingers with three or more cysteines defines the target proteins for oxidation by ROS. This represents a novel mechanism of selective protein oxidation and demonstrates how an environmental factor may sensitize certain target proteins for oxidation, thus altering the oxidation profile and redox regulation.     

Solution structure of the inhibitor of cysteine proteases 1 from Entamoeba histolytica reveals a possible auto regulatory mechanism

The genome of Entamoeba histolytica encodes approximately 50 Cysteine Proteases (CPs) whose activity is regulated by two Inhibitors of Cysteine Proteases (ICPs), EhICP1 and EhICP2. The main difference between both EhICPs is the acquisition of a 17 N-terminal targeting signal in EhICP2 and three exposed cysteine residues in EhICP1. The three exposed cysteines in EhICP1 potentiate the formation of cross-linking species that drive heterogeneity. Here we solved the NMR structure of EhICP1 using a mutant protein without accessible cysteines. Our structural data shows that EhICP1 adopts an immunoglobulin fold composed of seven β-strands, and three solvent exposed loops that resemble the structures of EhICP2 and chagasin. EhICP1 and EhICP2 are able to inhibit the archetypical cysteine protease papain by intercalating their BC loops into the protease active site independently of the character of the residue (serine or threonine) responsible to interact with the active site of papain. EhICP1 and EhICP2 present signals of functional divergence as they clustered in different clades. Two of the three exposed cysteines in EhICP1 are located at the DE loop that intercalates into the CP substrate-binding cleft. We propose that the solvent exposed cysteines of EhICP1 play a role in regulating its inhibitory activity and that in oxidative conditions, the cysteines of EhICP1 react to form intra and intermolecular disulfide bonds that render an inactive inhibitor. EhICP2 is not subject to redox regulation, as this inhibitor does not contain a single cysteine residue. This proposed redox regulation may be related to the differential cellular localization between EhICP1 and EhICP2.     

Mutation in a gene encoding anti-sigma factor in A. brasilense confers tolerance to elevated temperature, antibacterial peptide and PEG-200 via carotenoid synthesis

Azospirillum brasilense Sp7 has been shown to overproduce carotenoids if the anti-sigma factor (anti-sigma(E))-encoding gene is inactivated. The anti-sigma mutant (Car-1) of A. brasilense Sp7 was more tolerant to the stresses generated by elevated temperature (40 degrees C), PEG-200 (30 mg mL(-1)) and the antibacterial agent Polymyxin-B (PMB, 25 mug mL(-1)) but not to elevated salinity (15 mg mL(-1)). Inhibition of carotenoid synthesis by diphenylamine inhibited the ability of the mutant to tolerate all the three stresses. Out of the four stress agents, only elevated temperature and salinity induced the rpoE promoter and increased the carotenoid content in Sp7 as well as in the Car-1 mutant. Comparison of the membrane permeability of the parent and the mutant by a PMB-N-phenyl-1-naphthylamine coupled assay showed that the presence of carotenoids in the mutant reduced the permeability of their membranes. Our study indicates that the carotenoid synthesis, which is under the control of extracytoplasmic function sigma factor (sigma(E)) in A. brasilense Sp7, plays a positive role in tolerating elevated temperature, the antibacterial peptide and PEG-200.     

Respiratory chain strongly oxidizes the CXXC motif of DsbB in the Escherichia coli disulfide bond formation pathway

Escherichia coli DsbB has four essential cysteine residues, among which Cys41 and Cys44 form a CXXC redox active site motif and the Cys104-Cys130 disulfide bond oxidizes the active site cysteines of DsbA, the disulfide bond formation factor in the periplasm. Functional respiratory chain is required for the cell to keep DsbA oxidized. In this study, we characterized the roles of essential cysteines of DsbB in the coupling with the respiratory chain. Cys104 was found to form the inactive complex with DsbA under respiration-defective conditions. While DsbB, under normal aerobic conditions, is in the oxidized state, having two intramolecular disulfide bonds, oxidation of Cys104 and Cys130 requires the presence of Cys41-Cys44. Remarkably, the Cys41-Cys44 disulfide bond is refractory to reduction by a high concentration of dithiothreitol, unless the membrane is solubilized with a detergent. This reductant resistance requires both the respiratory function and oxygen, since Cys41-Cys44 became sensitive to the reducing agent when membrane was prepared from quinone- or heme-depleted cells or when a membrane sample was deaerated. Thus, the Cys41-Val-Leu-Cys44 motif of DsbB is kept both strongly oxidized and strongly oxidizing when DsbB is integrated into the membrane with the normal set of respiratory components.     

Dissecting the individual contribution of conserved cysteines to the redox regulation of RubisCO

Oxidation of the cysteines from ribulose 1,5-bisphosphate carboxylase/oxygenase (RubisCO) leads to inactivation and promotes structural changes that increase the proteolytic sensitivity and membrane association propensity related to its catabolism. To uncover the individual role of the different cysteines, the sequential order of modification under increasing oxidative conditions was determined using chemical labeling and mass spectrometry. Besides, site-directed RubisCO mutants were obtained in Chlamydomonas reinhardtii replacing single conserved cysteines (Cys84, Cys172, Cys192, Cys247, Cys284, Cys427, Cys459 from the large and sCys41, sCys83 from the small subunit) and the redox properties of the mutant enzymes were determined. All mutants retained significant carboxylase activity and grew photoautotrophically, indicating that these conserved cysteines are not essential for catalysis. Cys84 played a noticeable structural role, its replacement producing a structurally altered enzyme. While Cys247, Cys284, and sCys83 were not affected by the redox environment, all other residues were oxidized using a disulfide/thiol ratio of around two, except for Cys172 whose oxidation was distinctly delayed. Remarkably, Cys192 and Cys427 were apparently protective, their absence leading to a premature oxidation of critical residues (Cys172 and Cys459). These cysteines integrate a regulatory network that modulates RubisCO activity and conformation in response to oxidative conditions.     

The activation mechanism of human porphobilinogen synthase by 2-mercaptoethanol: intrasubunit transfer of a reserve zinc ion and coordination with three cysteines in the active center

Human porphobilinogen synthase [EC.4.2.1.24] is a homo-octamer enzyme. In the active center of each subunit, four cysteines are titrated with 5,5-dithiobis(2-nitrobenzoic acid). Cys¹²², Cys¹²⁴ and Cys¹³² are placed near two catalytic sites, Lys¹⁹⁹ and Lys²⁵², and coordinate a zinc ion, referred to as a proximal zinc ion, and Cys²²³ is placed at the orifice of the catalytic cavity and coordinates a zinc ion, referred to as a distal zinc ion, with His¹³¹ . When the wild-type enzymes C122A (Cys¹²²Ala), C124A (Cys¹²⁴Ala), C132A (Cys¹³²Ala) and C223A (Cys²²³Ala) were oxidized by hydrogen peroxide, the levels of activity were decreased. Two cysteines were titrated with 5,5-dithiobis(2-nitrobenzoic acid) in the wild-type enzyme, while on the other hand, one cysteine was titrated in the mutant enzymes. When wild-type and mutant enzymes were reduced by 2-mercaptoethanol, the levels of activity were increased: four and three cysteines were titrated, respectively, suggesting that a disulfide bond was formed among Cys¹²², Cys¹²⁴ and Cys¹³² under oxidizing conditions. We analyzed the enzyme-bound zinc ion of these enzymes using inductively coupled plasma mass spectrometry with gel-filtration chromatography. The results for C223A showed that the number of proximal zinc ions correlated to the level of enzymatic activity. Furthermore, zinc-ion-free 2-mercaptoethanol increased the activity of the wild-type enzyme without a change in the total number of zinc ions, but C223A was not activated. These findings suggest that a distal zinc ion moved to the proximal binding site when a disulfide bond among Cys¹²², Cys¹²⁴ and Cys¹³² was reduced by reductants. Thus, in the catalytic functioning of the enzyme, the distal zinc ion does not directly contribute but serves rather as a reserve as the next proximal one that catalyzes the enzyme reaction. A redox change of the three cysteines in the active center accommodates the catch and release of the reserve distal zinc ion placed at the orifice of the catalytic cavity.