Modulation of an Active-Site Cysteine pKa Allows PDI to Act as a Catalyst of both Disulfide Bond Formation and Isomerization

Protein disulfide isomerase (PDI) plays a central role in disulfide bond formation in the endoplasmic reticulum. It is implicated both in disulfide bond formation and in disulfide bond reduction and isomerization. To be an efficient catalyst of all three reactions requires complex mechanisms. These include mechanisms to modulate the pK_a values of the active-site cysteines of PDI. Here, we examined the role of arginine 120 in modulating the pK_a values of these cysteines. We find that arginine 120 plays a significant role in modulating the pK_a of the C-terminal active-site cysteine in the a domain of PDI and plays a role in determining the reactivity of the N-terminal active-site cysteine but not via direct modulation of its pK_a. Mutation of arginine 120 and the corresponding residue, arginine 461, in the a′ domain severely reduces the ability of PDI to catalyze disulfide bond formation and reduction but enhances the ability to catalyze disulfide bond isomerization due to the formation of more stable PDI-substrate mixed disulfides. These results suggest that the modulation of pK_a of the C-terminal active cysteine by the movement of the side chain of these arginine residues into the active-site locales has evolved to allow PDI to efficiently catalyze both oxidation and isomerization reactions.     

Structure of the Catalytic aa Fragment of the Protein Disulfide Isomerase ERp72

Protein disulfide isomerases (PDIs) are responsible for catalyzing the proper oxidation and isomerization of disulfide bonds of newly synthesized proteins in the endoplasmic reticulum (ER). The ER contains many different PDI-like proteins. Some, such as PDI, are general enzymes that directly recognize misfolded proteins while others, such as ERp57 and ERp72, have more specialized roles. Here, we report the high-resolution X-ray crystal structure of the N-terminal portion of ERp72 (also known as CaBP2 or PDI A4), which contains two a⁰a catalytic thioredoxin-like domains. The structure shows that the a⁰ domain contains an additional N-terminal β-strand and a different conformation of the β5-α4 loop relative to other thioredoxin-like domains. The structure of the a domain reveals that a conserved arginine residue inserts into the hydrophobic core and makes a salt bridge with a conserved glutamate residue in the vicinity of the catalytic site. A structural model of full-length ERp72 shows that all three catalytic sites roughly face each other and positions the adjacent hydrophobic patches that are likely involved in protein substrate binding.     

Redox properties of the A-domain of the HMGB1 protein

The High Mobility Group B1 (HMGB1) protein plays important roles in both intracellular (reductive) and extracellular (oxidative) environments. We have carried out quantitative investigations of the redox chemistry involving Cys22 and Cys44 of the HMGB1 A-domain, which form an intramolecular disulfide bond. Using NMR spectroscopy, we analyzed the real-time kinetics of the redox reactions for the A-domain in glutathione and thioredoxin systems, and also determined the standard redox potential. Thermodynamic experiments showed that the Cys22-Cys44 disulfide bond stabilizes the folded state of the protein. These data suggest that the oxidized HMGB1 may accumulate even in cells under oxidative stress.

Structured summary

MINT-6795963:

txn (uniprotkb:P10599) and HMGB1 (uniprotkb:P09429) bind (MI:0408) by nuclear magnetic resonance (MI:0077)

     

Redox, mutagenic and structural studies of the glutaredoxin/arsenate reductase couple from the cyanobacterium Synechocystis sp. PCC 6803

The arsenate reductase from the cyanobacterium Synechocystis sp. PCC 6803 has been characterized in terms of the redox properties of its cysteine residues and their role in the reaction catalyzed by the enzyme. Of the five cysteines present in the enzyme, two (Cys13 and Cys35) have been shown not to be required for catalysis, while Cys8, Cys80 and Cys82 have been shown to be essential. The as-isolated enzyme contains a single disulfide, formed between Cys80 and Cys82, with an oxidation-reduction midpoint potential (E_m) value of − 165 mV at pH 7.0. It has been shown that Cys15 is the only one of the four cysteines present in Synechocystis sp. PCC 6803 glutaredoxin A required for its ability to serve as an electron donor to arsenate reductase, while the other three cysteines (Cys18, Cys36 and Cys70) play no role. Glutaredoxin A has been shown to contain a single redox-active disulfide/dithiol couple, with a two-electron, E_m value of − 220 mV at pH 7.0. One cysteine in this disulfide/dithiol couple has been shown to undergo glutathionylation. An X-ray crystal structure, at 1.8 Å resolution, has been obtained for glutaredoxin A. The probable orientations of arsenate reductase disulfide bonds present in the resting enzyme and in a likely reaction intermediate of the enzyme have been examined by in silico modeling, as has the surface environment of arsenate reductase in the vicinity of Cys8, the likely site for the initial reaction between arsenate and the enzyme.     

Crystal structure of D-serine dehydratase from Escherichia coli

D-Serine dehydratase from Escherichia coli is a member of the β-family (fold-type II) of the pyridoxal 5′-phosphate-dependent enzymes, catalyzing the conversion of D-serine to pyruvate and ammonia. The crystal structure of monomeric D-serine dehydratase has been solved to 1.97 Å-resolution for an orthorhombic data set by molecular replacement. In addition, the structure was refined in a monoclinic data set to 1.55 Å resolution. The structure of DSD reveals a larger pyridoxal 5′-phosphate-binding domain and a smaller domain. The active site of DSD is very similar to those of the other members of the β-family. Lys118 forms the Schiff base to PLP, the cofactor phosphate group is liganded to a tetraglycine cluster Gly279-Gly283, and the 3-hydroxyl group of PLP is liganded to Asn170 and N1 to Thr424, respectively. In the closed conformation the movement of the small domain blocks the entrance to active site of DSD. The domain movement plays an important role in the formation of the substrate recognition site and the catalysis of the enzyme. Modeling of D-serine into the active site of DSD suggests that the hydroxyl group of D-serine is coordinated to the carboxyl group of Asp238. The carboxyl oxygen of D-serine is coordinated to the hydroxyl group of Ser167 and the amide group of Leu171 (O1), whereas the O2 of the carboxyl group of D-serine is hydrogen-bonded to the hydroxyl group of Ser167 and the amide group of Thr168. A catalytic mechanism very similar to that proposed for L-serine dehydratase is discussed.     

The Asymmetric Flagellar Distribution and Motility of Escherichia coli

Rod-shaped bacteria such as Escherichia coli divide by binary fission. They inherit an old pole from the parent cell. The new pole is recently derived from the septum. Because the chemoreceptor accumulates linearly with time on the cell pole, the old pole carries more receptors than does the new pole. Here, further evidence is provided that the old pole appears more frequently at the rear when bacteria swim. This phenomenon had been observed, yet not extensively explored in the literature. The biased swimming orientation is the consequence of the asymmetric distribution of flagella over the cell surface. On about 75% of cells, there are more flagella on the old-pole half of the cell than on the new-pole half, regardless of growth conditions. Most flagella are lateral, and few were found on the cell pole per se. The asymmetric flagellar distribution makes cells more efficient in chemotaxis. Both swimming orientation and receptor localization are components of chemotaxis, by which bacteria follow environmental stimuli. If unipolarly flagellated cells, such as the swarmer cells of Caulobacter crescentus, are regarded as 100% polar with respect to chemotaxis, E. coli is about 75%. The difference is quantitative. The peritrichous flagellation might enhance the motility and chemotaxis in the viscous environment of enteric bacteria.     

Understanding nicotinamide dinucleotide cofactor and substrate specificity in class I flavoprotein disulfide oxidoreductases: crystallographic analysis of a glutathione amide reductase

Glutathione reductase (GR) plays a vital role in maintaining the antioxidant levels of the cytoplasm by catalyzing the reduction of glutathione disulfide to reduced glutathione, thereby using NADPH and flavin adenine dinucleotide as cofactors. Chromatiaceae have evolved an unusual homolog that prefers both a modified substrate (glutathione amide disulfide [GASSAG]) and a different cofactor (NADH). Herein, we present the crystal structure of the Chromatium gracile glutathione amide reductase (GAR) both alone and in complex with NAD⁺. An altered charge distribution in the GASSAG binding pocket explains the difference in substrate specificity. The NADH binding pocket of GAR differs from that of wild-type GR as well as that of a low active GR that was engineered to mimic NADH binding. Based on the GAR structure, we propose two attractive rationales for producing an efficient GR enzyme with NADH specificity.     

Structural basis for the different activities of yeast Grx1 and Grx2

Yeast glutaredoxins Grx1 and Grx2 catalyze the reduction of both inter- and intra-molecular disulfide bonds using glutathione (GSH) as the electron donor. Although sharing the same dithiolic CPYC active site and a sequence identity of 64%, they have been proved to play different roles during oxidative stress and to possess different glutathione-disulfide reductase activities. To address the structural basis of these differences, we solved the crystal structures of Grx2 in oxidized and reduced forms, at 2.10 Å and 1.50 Å, respectively. With the Grx1 structures we previously reported, comparative structural analyses revealed that Grx1 and Grx2 share a similar GSH binding site, except for a single residue substitution from Asp89 in Grx1 to Ser123 in Grx2. Site-directed mutagenesis in combination with activity assays further proved this single residue variation is critical for the different activities of yeast Grx1 and Grx2.     

The site for the allosteric activator GTP of Escherichia coli UMP kinase

UMP kinase (UMPK), a key bacterial pyrimidine nucleotide biosynthesis enzyme, is UTP-inhibited and GTP-activated. We delineate the GTP site of Escherichia coli UMPK by alanine mutagenesis of R92, H96, R103, W119 or R130, abolishing GTP activation; of S124 and R127, decreasing affinity for GTP; and of N111 and D115, with little detrimental effect. We exclude the correspondence with the modulatory ATP site of Bacillus anthracis UMPK, confirming the functionality of the GTP site found by Evrin. Mutants R92A, H96A and R127A are constitutively activated, suggesting key roles of these residues in allosteric signal transduction and of positive charge neutralization in triggering activation. No mutation hampered UTP inhibition, excluding overlapping of the UTP and GTP sites.     

Time-Resolved Binding of Azithromycin to Escherichia coli Ribosomes

Azithromycin is a semisynthetic derivative of erythromycin that inhibits bacterial protein synthesis by binding within the peptide exit tunnel of the 50S ribosomal subunit. Nevertheless, there is still debate over what localization is primarily responsible for azithromycin binding and as to how many molecules of the drug actually bind per ribosome. In the present study, kinetic methods and footprinting analysis are coupled together to provide time-resolved details of the azithromycin binding process. It is shown that azithromycin binds to Escherichia coli ribosomes in a two-step process: The first-step involves recognition of azithromycin by the ribosomal machinery and places the drug in a low-affinity site located in the upper part of the exit tunnel. The second step corresponds to the slow formation of a final complex that is both much tighter and more potent in hindering the progression of the nascent peptide through the exit tunnel. Substitution of uracil by cytosine at nucleoside 2609 of 23S rRNA, a base implicated in the high-affinity site, facilitates the shift of azithromycin to this site. In contrast, mutation U754A hardly affects the binding process. Binding of azithromycin to both sites is hindered by high concentrations of Mg²⁺ ions. Unlike Mg²⁺ ions, polyamines do not significantly affect drug binding to the low-affinity site but attenuate the formation of the final complex. The low- and high-affinity sites of azithromycin binding are mutually exclusive, which means that one molecule of the drug binds per E. coli ribosome at a time. In contrast, kinetic and binding data indicate that in Deinococcus radiodurans, two molecules of azithromycin bind cooperatively to the ribosome. This finding confirms previous crystallographic results and supports the notion that species-specific structural differences may primarily account for the apparent discrepancies between the antibiotic binding modes obtained for different organisms.     

The role of the invariant glutamate 95 in the catalytic site of Complex I from Escherichia coli

Replacement of glutamate 95 for glutamine in the NADH- and FMN-binding NuoF subunit of E. coli Complex I decreased NADH oxidation activity 2.5-4.8 times depending on the used electron acceptor. The apparent K_m for NADH was 5.2 and 10.4 μM for the mutant and wild type, respectively. Analysis of the inhibitory effect of NAD⁺ on activity showed that the E95Q mutation caused a 2.4-fold decrease of K_i^NAD+ in comparison to the wild type enzyme. ADP-ribose, which differs from NAD⁺ by the absence of the positively charged nicotinamide moiety, is also a competitive inhibitor of NADH binding. The mutation caused a 7.5-fold decrease of K_i^ADP-ribose relative to wild type enzyme. Based on these findings we propose that the negative charge of Glu95 accelerates turnover of Complex I by electrostatic interaction with the negatively charged phosphate groups of the substrate nucleotide during operation, which facilitates release of the product NAD⁺. The E95Q mutation was also found to cause a positive shift of the midpoint redox potential of the FMN, from − 350 mV to − 310 mV, which suggests that the negative charge of Glu95 is also involved in decreasing the midpoint potential of the primary electron acceptor of Complex I.     

Molecular Mechanism of Polypeptide Translocation Catalyzed by the Escherichia coli ClpA Protein Translocase

The removal of damaged or unneeded proteins by ATP-dependent proteases is crucial for cell survival in all organisms. Integral components of ATP-dependent proteases are motor proteins that unfold stably folded proteins that have been targeted for removal. These protein unfoldases/polypeptide translocases use ATP to unfold the target proteins and translocate them into a proteolytic component. Despite the central role of these motor proteins in cell homeostasis, a number of important questions regarding the molecular mechanisms of enzyme catalyzed protein unfolding and translocation remain unanswered. Here, we demonstrate that Escherichia coli ClpA, in the absence of the proteolytic component ClpP, processively and directionally steps along the polypeptide backbone with a kinetic step size of ∼ 14 amino acids, independent of the concentration of ATP with a rate of ∼ 19 amino acids s⁻¹ at saturating concentrations of ATP. In contrast to earlier studies by others, we have developed single-turnover fluorescence stopped-flow methods that allow us to quantitatively examine the molecular mechanism of the motor component ClpA decoupled from the proteolytic component ClpP. For the first time, we reveal that in the absence of ClpP ClpA translocates polypeptides directionally, processively and in discrete steps similar to other motor proteins that translocate vectorially on a linear lattice, such as nucleic acid helicases and kinesin. We believe that the methods employed here will be generally applicable to the examination of other AAA?+ protein translocases involved in a variety of important biological functions where the substrate is not covalently modified; for example, membrane fusion, membrane transport, protein disaggregation, and protein refolding.     

The purification of methionine sulfoxide reductase from Escherichia coli

A sensitive assay, based on the acylation of tRNA^Met, has been developed to measure the enzymatic reduction of methionine sulfoxide to methionine. Using this assay, methionine sulfoxide reductase has been purified to near homogeneity from extracts of Escherichia coli.     

Two endoplasmic reticulum PDI peroxidases increase the efficiency of the use of peroxide during disulfide bond formation

Disulfide bond formation in the endoplasmic reticulum by the sulfhydryl oxidase Ero1 family is thought to be accompanied by the concomitant formation of hydrogen peroxide. Since secretory cells can make substantial amounts of proteins that contain disulfide bonds, the production of this reactive oxygen species could have potentially lethal consequences. Here, we show that two human proteins, GPx7 and GPx8, labeled as secreted glutathione peroxidases, are actually endoplasmic reticulum-resident protein disulfide isomerase peroxidases. In vitro, the addition of GPx7 or GPx8 to a folding protein along with protein disulfide isomerase and peroxide enables the efficient oxidative refolding of a reduced denatured protein. Furthermore, both GPx7 and GPx8 interact with Ero1α in vivo, and GPx7 significantly increases oxygen consumption by Ero1α in vitro. Hence, GPx7 and GPx8 may represent a novel route for the productive use of peroxide produced by Ero1α during disulfide bond formation.     

Plasmodium falciparum antioxidant protein as a model enzyme for a special class of glutaredoxin/glutathione-dependent peroxiredoxins

Background

Peroxiredoxins are important heterogeneous thiol-dependent hydroperoxidases with a variety of isoforms and enzymatic mechanisms. A special subclass of glutaredoxin/glutathione-dependent peroxiredoxins has been discovered in bacteria and eukaryotes during the last decade, but the exact enzymatic mechanisms of these enzymes remain to be unraveled.

Methods

We performed a comprehensive analysis of the enzyme kinetics and redox states of one of these glutaredoxin/glutathione-dependent peroxiredoxins, the antioxidant protein from the malaria parasite Plasmodium falciparum, using steady-state kinetic measurements, site-directed mutagenesis, redox mobility shift assays, gel filtration, and mass spectrometry.

Results

P. falciparum antioxidant protein requires not only glutaredoxin but also glutathione as a true substrate for the reduction of hydroperoxides. One peroxiredoxin cysteine residue and one glutaredoxin cysteine residue are sufficient for catalysis, however, additional cysteine residues of both proteins result in alternative redox states and conformations in vitro with implications for redox regulation. Our data furthermore point to a glutathione-dependent peroxiredoxin activation and a negative subunit cooperativity.

Conclusions

The investigated glutaredoxin/glutathione/peroxiredoxin system provides numerous new insights into the mechanism and redox regulation of peroxiredoxins.

General significance

As a member of the special subclass of glutaredoxin/glutathione-dependent peroxiredoxins, the P. falciparum antioxidant protein could become a reference protein for peroxiredoxin catalysis and regulation.     

Interaction of fosfomycin with the Glycerol 3-phosphate Transporter of Escherichia coli

Background

Fosfomycin is widely used to treat urinary tract and pediatric gastrointestinal infections of bacteria. It is supposed that this antibiotic enters cells via two transport systems, including the bacterial Glycerol-3-phosphate Transporter (GlpT). Impaired function of GlpT is one mechanism for fosfomycin resistance.

Methods

The interaction of fosfomycin with the recombinant and purified GlpT of Escherichia coli reconstituted in liposomes has been studied. IC₅₀ and the half-saturation constant of the transporter for external fosfomycin (K_i) were determined by transport assay of [¹⁴C]glycerol-3-phosphate catalyzed by recombinant GlpT. Efficacy of fosfomycin on growth rates of GlpT defective bacteria strains transformed with recombinant GlpT was measured.

Results

Fosfomycin, externally added to the proteoliposomes, poorly inhibited the glycerol-3-phosphate/glycerol-3-phosphate antiport catalyzed by the reconstituted transporter with an IC₅₀ of 6.4 mM. A kinetic analysis revealed that the inhibition was completely competitive, that is, fosfomycin interacted with the substrate-binding site and the K_i measured was 1.65 mM. Transport assays performed with proteoliposomes containing internal fosfomycin indicate that it was not very well transported by GlpT. Complementation study, performed with GlpT defective bacteria strains, indicated that the fosfomycin resistance, beside deficiency in antibiotic transporter, could be due to other gene defects.

Conclusions

The poor transport observed in a reconstituted system together with the high value of K_i and the results of complementation study well explain the usual high dosage of this drug for the treatment of the urinary tract infections.

General significance

This is the first report regarding functional analysis of interaction between fosfomycin and GlpT.     

The cellular redox state as a modulator in cadmium and copper responses in Arabidopsis thaliana seedlings

The cellular redox state is an important determinant of metal phytotoxicity. In this study we investigated the influence of cadmium (Cd) and copper (Cu) stress on the cellular redox balance in relation to oxidative signalling and damage in Arabidopsis thaliana. Both metals were easily taken up by the roots, but the translocation to the aboveground parts was restricted to Cd stress. In the roots, Cu directly induced an oxidative burst, whereas enzymatic ROS (reactive oxygen species) production via NADPH oxidases seems important in oxidative stress caused by Cd. Furthermore, in the roots, the glutathione metabolism plays a crucial role in controlling the gene regulation of the antioxidative defence mechanism under Cd stress. Metal-specific alterations were also noticed with regard to the microRNA regulation of CuZnSOD gene expression in both roots and leaves. The appearance of lipid peroxidation is dual: it can be an indication of oxidative damage as well as an indication of oxidative signalling as lipoxygenases are induced after metal exposure and are initial enzymes in oxylipin biosynthesis.In conclusion, the metal-induced cellular redox imbalance is strongly dependent on the chemical properties of the metal and the plant organ considered. The stress intensity determines its involvement in downstream responses in relation to oxidative damage or signalling.     

Unfolding and breakdown of insulin in the presence of endogenous thiols

Native insulin denatures and unfolds in the presence of thiol catalyst via disulfide scrambling (isomerization). It undergoes two transient non-native conformational isomers, followed by an irreversible breakdown of the protein to form oxidized A- and B-chain. Denaturation and breakdown of native insulin may occur under physiological conditions. At 37 degrees C, pH 7.4, and in the presence of cysteine (0.2 mM), native insulin decomposes with a pseudo first order kinetic of 0.075 h(-1). At 50 degrees C, the rate increases by 5-fold. GdnCl and urea induced denaturation of insulin follows the same mechanism. These results demonstrate that stability and unfolding pathway of insulin in the presence of endogenous thiol differ fundamentally from its reversible denaturation observed in the absence of thiol, in which native disulfide bonds of insulin were kept intact during the process of denaturation.