Single-site oxidation, cysteine 108 to cysteine sulfinic acid, in D-amino acid oxidase from Trigonopsis variabilis and its structural and functional consequences

One of the primary sources of enzyme instability is protein oxidative modification triggering activity loss or denaturation. We show here that the side chain of Cys108 is the main site undergoing stress-induced oxidation in Trigonopsis variabilis d-amino acid oxidase, a flavoenzyme employed industrially for the conversion of cephalosporin C. High-resolution anion-exchange chromatography was used to separate the reduced and oxidized protein forms, which constitute, in a molar ratio of about 3:1, the active biocatalyst isolated from the yeast. Comparative analysis of their tryptic peptides by electrospray tandem mass spectrometry allowed unequivocal assignment of the modification as the oxidation of Cys108 into cysteine sulfinic acid. Cys108 is likely located on a surface-exposed protein region within the flavin adenine dinucleotide (FAD) binding domain, but remote from the active center. Its oxidized side chain was remarkably stable in solution, thus enabling the relative biochemical characterization of native and modified enzyme forms. The oxidation of Cys108 causes a global conformational response that affects the protein environment of the FAD cofactor. In comparison with the native enzyme, it results in a fourfold-decreased specific activity, reflecting a catalytic efficiency for reduction of dioxygen lowered by about the same factor, and a markedly decreased propensity to aggregate under conditions of thermal denaturation. These results open up unprecedented routes for stabilization of the oxidase and underscore the possible significance of protein chemical heterogeneity for biocatalyst function and stability.     

Thermostable Xanthine Oxidase Activity from <Emphasis Type="Italic">Bacillus pumilus</Emphasis> RL-2d Isolated from Manikaran Thermal Spring: Production and Characterization

Xanthine oxidase is an important enzyme of purine metabolism that catalyzes the hydroxylation of hypoxanthine to xanthine and then xanthine to uric acid. A thermostable xanthine oxidase is being reported from a thermophilic organism RL-2d isolated from the Manikaran (Kullu) hot spring of Himachal Pradesh (India). Based on the morphology, physiological tests, and 16S rDNA gene sequence, RL-2d was identified as Bacillus pumilus. Optimization of physiochemical parameters resulted into 4.1-fold increase in the xanthine oxidase activity from 0.051 U/mg dcw (dry cell weight) to 0.209 U/mg dcw. The xanthine oxidase of B. pumilus RL-2d has exhibited very good thermostability and its t_1/2 at 70 and 80 °C were 5 and 1 h, respectively. Activity of this enzyme was strongly inhibited by Hg²⁺, Ag⁺ and allopurinol. The investigation showed that B. pumilus RL-2d exhibited highest xanthine oxidase activity and remarkable thermostability among the other xanthine oxidases reported so far.     

Cross-linked cell aggregates of Trigonopsis variabilis: D-amino acid oxidase catalyst for oxidation of cephalosporin C

Trigonopsis variabilis CBS 4095 was treated with alkali (pH 11, 30 min), heated (65°C, 60 s) and immobilized. Glutaraldehyde, polyethyleneimine and a cross-linking reagent formed by reaction of polyethyleneimine with glutaraldehyde were used for stabilization of d-amino acid oxidase in the cells, as well as for aggregation and binding of the cells. A specific activity of 82–98 U of d-amino acid oxidase per g dry mass was produced with a yield of about 20%. The half-life time of 142 repeated conversion cycles corresponds to a productivity of 130 kg cephalosporin C oxidized per kg catalyst dry mass.     

Crystal Structure of Sulfide:Quinone Oxidoreductase from Acidithiobacillus ferrooxidans: Insights into Sulfidotrophic Respiration and Detoxification

Sulfide:quinone oxidoreductase from the acidophilic and chemolithotrophic bacterium Acidithiobacillus ferrooxidans was expressed in Escherichia coli and crystallized, and its X-ray molecular structure was determined to 2.3 Å resolution for native unbound protein in space group P4₂2₁2 . The decylubiquinone-bound structure and the Cys160Ala variant structure were subsequently determined to 2.3 Å and 2.05 Å resolutions, respectively, in space group P6₂22  . The enzymatic reaction catalyzed by sulfide:quinone oxidoreductase includes the oxidation of sulfide compounds H₂S, HS⁻, and S²⁻ to soluble polysulfide chains or to elemental sulfur in the form of octasulfur rings; these oxidations are coupled to the reduction of ubiquinone or menaquinone. The enzyme comprises two tandem Rossmann fold domains and a flexible C-terminal domain encompassing two amphipathic helices that are thought to provide for membrane anchoring. The second amphipathic helix unwinds and changes its orientation in the hexagonal crystal form. The protein forms a dimer that could be inserted into the membrane to a depth of approximately 20 Å. It has an endogenous flavin adenine dinucleotide (FAD) cofactor that is noncovalently bound in the N-terminal domain. Several wide channels connect the FAD cofactor to the exterior of the protein molecule; some of the channels would provide access to the membrane. The ubiquinone molecule is bound in one of these channels; its benzoquinone ring is stacked between the aromatic rings of two conserved Phe residues, and it closely approaches the isoalloxazine moiety of the FAD cofactor. Two active-site cysteine residues situated on the re side of the FAD cofactor form a branched polysulfide bridge. Cys356 disulfide acts as a nucleophile that attacks the C4A atom of the FAD cofactor in electron transfer reaction. The third essential cysteine Cys128 is not modified in these structures; its role is likely confined to the release of the polysulfur product.     

The isocitrate dehydrogenase kinase/phosphatase from Escherichia coli is highly sensitive to in-vitro oxidative conditions role of cysteine67 and cysteine108 in the formation of a disulfide-bonded homodimer.

Isocitrate dehydrogenase kinase/phosphatase (IDHK/P) is a homodimeric enzyme which controls the oxidative metabolism of Escherichia coli, and exibits a high intrinsic ATPase activity. When subjected to electrophoresis under nonreducing conditions, the purified enzyme migrates partially as a dimer. The proportion of the dimer over the monomer is greatly increased by treatment with cupric 1,10 phenanthrolinate or 5,5'-dithio-bis(2-nitrobenzoic acid), and fully reversed by dithiothreitol, indicating that covalent dimerization is produced by a disulfide bond. To identify the residue(s) involved in this intermolecular disulfide-bond, each of the eight cysteines of the enzyme was individually mutated into a serine. It was found that, under nonreducing conditions, the electrophoretic patterns of all corresponding mutants are identical to that of the wild-type, except for the Cys67-->Ser which migrates exclusively as a monomer and for the Cys108-->Ser which migrates preferentially as a dimer. Furthermore, in contrast to the wild-type enzyme and all the other mutants, the Cys67-->Ser mutant still migrates as a monomer after treatment with cupric 1,10 phenanthrolinate. This result indicates that the intermolecular disulfide bond involves only Cys67 in each IDHK/P wild-type monomer. This was further supported by mass spectrum analysis of the tryptic peptides derived from either the cupric 1,10 phenanthrolinate-treated wild-type enzyme or the native Cys108-->Ser mutant, which show that they both contain a Cys67-Cys67 disulfide bond. Moreover, both the cupric 1,10 phenanthrolinate-treated wild-type enzyme and the native Cys108-->Ser mutant contain another disulfide bond between Cys356 and Cys480. Previous results have shown that this additional Cys356-Cys480 disulfide bond is intramolecular [Oudot, C., Jault, J.-M., Jaquinod, M., Negre, D., Prost, J.-F., Cozzone, A.J. & Cortay, J.-C. (1998) Eur. J. Biochem. 258, 579-585].     

Redox regulation of UDP-glucose pyrophosphorylase from Entamoeba histolytica

Amoebiasis is an intestinal infection caused by the human pathogen Entamoeba histolytica and representing the third leading cause of death by parasites in the world. Host-parasite interactions mainly involve anchored glycoconjugates localized in the surface of the parasitic cell. In protozoa, synthesis of structural oligo- and polysaccharides occurs via UDP-glucose, generated in a reaction catalyzed by UDP-glucose pyrophosphorylase. We report the molecular cloning of the gene coding for this enzyme from genomic DNA of E. histolytica and its recombinant expression in Escherichia coli cells. The purified enzyme was kinetically characterized, catalyzing UDP-glucose synthesis and pyrophosphorolysis with V_max values of 95 U/mg and 3 U/mg, respectively, and affinity for substrates comparable to those found for the enzyme from other sources. Enzyme activity was affected by redox modification of thiol groups. Different oxidants, including diamide, hydrogen peroxide and sodium nitroprusside inactivated the enzyme. The process was completely reverted by reducing agents, mainly cysteine, dithiothreitol, and thioredoxin. Characterization of the enzyme mutants C94S, C108S, C191S, C354S, C378S, C108/378S, M106S and M106C supported a molecular mechanism for the redox regulation. Molecular modeling confirmed the role of specific cysteine and methionine residues as targets for redox modification in the entamoebic enzyme. Our results suggest that UDP-glucose pyrophosphorylase is a regulated enzyme in E. histolytica. Interestingly, results strongly agree with the occurrence of a physiological redox mechanism modulating enzyme activity, which would critically affect carbohydrate metabolism in the protozoon.     

The structure of a bacterial L-amino acid oxidase from Rhodococcus opacus gives new evidence for the hydride mechanism for dehydrogenation

l-Amino acid oxidase from Rhodococcus opacus (roLAAO) is classified as a member of the GR(2)-family of flavin-dependent oxidoreductases according to a highly conserved sequence motif for the cofactor binding. The monomer of the homodimeric enzyme consists of three well-defined domains: the FAD-binding domain corresponding to a general topology throughout the whole GR(2)-family; a substrate-binding domain with almost the same topology as the snake venom LAAO and a helical domain exclusively responsible for the unusual dimerisation mode of the enzyme and not found in other members of the family so far. We describe here high-resolution structures of the binary complex of protein and cofactor as well as the ternary complexes of protein, cofactor and ligands. This structures in addition to the structural knowledge of snake venom LAAO and DAAO from yeast and pig kidney permit more insight into different steps in the reaction mechanism of this class of enzymes. There is strong evidence for hydride transfer as the mechanism of dehydrogenation. This mechanism appears to be uncommon in a sense that the chemical transformation can proceed efficiently without the involvement of amino acid functional groups. Most groups present at the active site are involved in substrate recognition, binding and fixation, i.e. they direct the trajectory of the interacting orbitals. In this mode of catalysis orbital steering/interactions are the predominant factors for the chemical step(s). A mirror-symmetrical relationship between the two substrate-binding sites of d and l-amino acid oxidases is observed which facilitates enantiomeric selectivity while preserving a common arrangement of the residues in the active site. These results are of general relevance for the mechanism of flavoproteins and lead to the proposal of a common dehydrogenation step in the mechanism for l and d-amino acid oxidases.     

Thermal inactivation of D-amino acid oxidase from Trigonopsis variabilis occurs via three parallel paths of irreversible denaturation

Trigonopsis variabilis D-amino acid oxidase (TvDAO) is a long-known flavoenzyme whose most important biocatalytic application is currently the industrial production of 7-amino-cephalosporanic acid (7-ACA) from cephalosporin C. Lacking mechanistic foundation, rational stabilization of TvDAO for improved process performance remains a problem. We report on results of thermal denaturation studies at 50 degrees C in which two purified TvDAO forms were compared: the native enzyme, and a site-specifically oxidized protein variant that had the side chain of cysteine108 converted into a sulfinic acid and lost 75% of original specific activity. Although inactivation time courses for both enzymes are fairly well described by simple single-exponential decays, the underlying denaturation mechanisms are shown by experiments and modeling to be complex. One main path leading to inactivation is FAD release, a process whose net rate is determined by the reverse association rate constant (k), which is 25-fold lower in the oxidized form of TvDAO. Cofactor dissociation is kinetically coupled to aggregation and can be blocked completely by the addition of free FAD. Aggregation is markedly attenuated in the less stable Cys108-SO(2)H-containing enzyme, suggesting that it is a step accompanying but not causing the inactivation. A second parallel path, characterized by a k-value of 0.26/h that is not dependent on protein concentration and identical for both enzymes, likely reflects thermal unfolding reactions. A third, however, slow process is the conversion of the native enzyme into the oxidized form (k < 0.03/h). The results fully explain the different stabilities of native and oxidized TvDAO and provide an inactivation mechanism-based tool for the stabilization of the soluble oxidase.     

Unique regulation of the active site of the serine esterase S-formylglutathione hydrolase

S-Formylglutathione hydrolases (SFGHs) are highly conserved thioesterases present in prokaryotes and eukaryotes, and form part of the formaldehyde detoxification pathway, as well as functioning as xenobiotic-hydrolysing carboxyesterases. As defined by their sensitivity to covalent modification, SFGHs behave as cysteine hydrolases, being inactivated by thiol alkylating agents, while being insensitive to inhibition by organophosphates such as paraoxon. As such, the enzyme has been classified as an esterase D in animals, plants and microbes. While SFGHs do contain a conserved cysteine residue that has been implicated in catalysis, sequence analysis also reveals the classic catalytic triad of a serine hydrolase. Using a combination of selective protein modification and X-ray crystallography, AtSFGH from Arabidopsis thaliana has been shown to be a serine hydrolase rather than a cysteine hydrolase. Uniquely, the conserved reactive cysteine (Cys59) previously implicated in catalysis lies in close proximity to the serine hydrolase triad, serving a gate-keeping function in comprehensively regulating access to the active site. Thus, any covalent modification of Cys59 inhibited all hydrolase activities of the enzyme. When isolated from Escherichia coli, a major proportion of recombinant AtSFGH was recovered with the Cys59 forming a mixed disulfide with glutathione. Reversible disulfide formation with glutathione could be demonstrated to regulate hydrolase activity in vitro. The importance of Cys59 in regulating AtSFGH in planta was demonstrated in transient expression assays in Arabidopsis protoplasts. As determined by fluorescence microscopy, the Cys59Ser mutant enzyme was shown to rapidly hydrolyse 4-methylumbelliferyl acetate in paraoxon-treated cells, while the native enzyme was found to be inactive. Our results clarify the classification of AtSFGHs as hydrolases and suggest that the regulatory and conserved cysteine provides an unusual redox-sensitive regulation to an enzyme functioning in both primary and xenobiotic metabolism in prokaryotes and eukaryotes.     

Catalytic acid/base residues of glutamate racemase

Glutamate racemase is a cofactor-independent enzyme that employs two active-site cysteine residues as acid/base catalysts during the interconversion of glutamate enantiomers. In a given reaction direction, a thiolate from one of the cysteines abstracts the alpha-proton, and the other cysteine thiol delivers a proton to the opposite face of the resulting carbanionic intermediate. This paper reports that the C73S and C184S mutants are still capable of racemizing glutamate with specificity constants about 10(3)-fold lower than those of the wild-type enzyme. A "one-base requiring" reaction, the elimination of water from N-hydroxyglutamate, has been used to deduce which thiol acts as the base for a given enantiomer. With D-N-hydroxyglutamate the C73S mutant is a much poorer catalyst than wild-type enzyme, whereas the C184S mutant is a somewhat better catalyst. This trend was reversed with L-N-hydroxyglutamate, suggesting that Cys73 is responsible for the deprotonation of D-glutamate and Cys184 is responsible for the deprotonation of L-glutamate. In addition, with C73S the Vmax/KM isotope effect on D-glutamate racemization was greater than that seen with wild-type enzyme, whereas the isotope effect with L-glutamate had decreased. The results were reversed with the C184S mutant. This is interpreted as being due to an asymmetry in the free energy profiles that is induced upon mutation, with the deprotonation step involving a serine becoming the more cleanly rate-determining of the two. These results support the above assignment and the notion that a carbanionic intermediate is formed during catalysis.     

Characterization of active site residues of nitroalkane oxidase

The flavoenzyme nitroalkane oxidase catalyzes the oxidation of primary and secondary nitroalkanes to the corresponding aldehydes and ketones plus nitrite. The structure of the enzyme shows that Ser171 forms a hydrogen bond to the flavin N5, suggesting that it plays a role in catalysis. Cys397 and Tyr398 were previously identified by chemical modification as potential active site residues. To more directly probe the roles of these residues, the S171A, S171V, S171T, C397S, and Y398F enzymes have been characterized with nitroethane as substrate. The C397S and Y398 enzymes were less stable than the wild-type enzyme, and the C397S enzyme routinely contained a substoichiometric amount of FAD. Analysis of the steady-state kinetic parameters for the mutant enzymes, including deuterium isotope effects, establishes that all of the mutations result in decreases in the rate constants for removal of the substrate proton by ∼5-fold and decreases in the rate constant for product release of ∼2-fold. Only the S171V and S171T mutations alter the rate constant for flavin oxidation. These results establish that these residues are not involved in catalysis, but rather are required for maintaining the protein structure.     

The reactivity of thiol groups in bovine heart cytochrome c oxidase towards 5,5′-dithiobis(2-nitrobenzoic acid)

Bovine heart cytochrome c oxidase consists of 12 stoicheiometric polypeptide chains of at least 11 different types. The enzyme contains 14–16 cysteine residues; the distribution of nearly all cysteine residues over the subunits has been established. In native cytochrome c oxidase two thiol groups reacted rapidly and stoicheiometrically with 5,5′-dithiobis(2-nitrobenzoic acid) (DTNB). These thiol groups are located in subunits I and III, respectively. This implies that subunit I is not fully buried in the hydrophobic core of the enzyme. After dissociation of the enzyme by sodium dodecyl sulphate more thiol groups became available to DTNB, in addition to those in subunits I and III, at least one in subunit II, two in fraction V/VI and one to two in the smallest subunit fraction. It is shown that separation of the subunits of cytochrome c oxidase by gel permeation chromatography in the presence of sodium dodecyl sulphate depends on the pH of the elution medium. The elution volume of subunits I, III and VII is dependent on pH, that of the others independent.     

Selective modification of surface-exposed thiol groups in Trigonopsis variabilis D-amino acid oxidase using poly(ethylene glycol) maleimide and its effect on activity and stability of the enzyme

Covalent modification of purified Trigonopsis variabilis D-amino acid oxidase using maleimide-activated poly(ethylene glycol) 5000 yielded a stable bioconjugate in which three surface-exposed cysteine side chains were selectively derivatized. Compared with the native enzyme, the PEGylated variant displayed substantially (approximately 3.3-fold) slowed dissociation rate of FAD cofactor at 50 degrees C, and this caused a twofold thermostabilization of the enzyme activity. The stability under reaction conditions at 30 degrees C was also markedly enhanced in the PEG-oxidase conjugate. PEGylation did not affect steady-state kinetic parameters for oxidative deamination of D-methionine when 2,6-dichloroindophenol replaced dioxygen as the cosubstrate while it caused a ninefold decrease in substrate catalytic efficiency for the dioxygen-dependent reaction.     

Improved thermostability and PCR efficiency of Thermococcus celericrescens DNA polymerase via site-directed mutagenesis

The Thermococcus celericrescens (Tcel) DNA polymerase gene, which contains a 2328-bp open reading frame that encodes 775 amino acid residues, was expressed in the Escherichia coli strain Rosetta(DE3)pLysS. The expressed enzyme was purified through heat treatment, HisTrap™ HP column chromatography and then HiTrap™ SP HP column chromatography. Tcel DNA polymerase has poor thermostability and PCR efficiency compared to those of other family B DNA polymerases. To improve thermostability and PCR efficiency, mutant Tcel DNA polymerases were created via site-directed mutagenesis. Specifically, we targeted the A752 residue for enhanced thermostability and the N213 residue for improved PCR efficiency. The mutant Tcel DNA polymerases all showed enhanced PCR efficiency and thermostability compared to those of the wild-type Tcel DNA polymerase. Specifically, the double mutant TcelA752K/N213D DNA polymerase had an approximately three-fold increase in thermostability over that of the wild-type enzyme and amplified a long 10-kb PCR product in an extension time of 2 min. However, there was a small change in the 3′ → 5′ exonuclease activity compared with that of the wild-type Tcel DNA polymerase, even though the mutation is in the ExoII motif. The double mutant TcelA752K/N213D DNA polymerase had a 2.6-fold lower error rate compared to that of Taq DNA polymerase. It seems that the double mutant TcelA752K/N213D DNA polymerase can be used in LA (long and accurate) PCR.     

The [4Fe-4S] cluster of quinolinate synthase from Escherichia coli: investigation of cluster ligands

Nicotinamide adenine dinucleotide (NAD) derives from quinolinic acid which is synthesized in Escherichia coli from l-aspartate and dihydroxyacetone phosphate through the concerted action of l-aspartate oxidase and the [4Fe-4S] quinolinate synthase (NadA). Here, we addressed the question of the identity of the cluster ligands. We performed in vivo complementation experiments as well as enzymatic, spectroscopic and structural in vitro studies using wild-type vs. Cys-to-Ala mutated NadA proteins. These studies reveal that only three cysteine residues, the conserved Cys113, Cys200 and Cys297, are ligands of the cluster. This result is in contrast to the previous proposal that pointed the three cysteines of the C(291)XXC(294)XXC(297) motif. Interestingly, we demonstrated that Cys291 and Cys294 form a disulfide bridge and are important for activity.     

Formation and properties of mixed disulfides between thioredoxin reductase from Escherichia coli and thioredoxin: evidence that cysteine-138 functions to initiate dithiol-disulfide interchange and to accept the reducing equivalent from reduced flavin.

Mutation of one of the cysteine residues in the redox active disulfide of thioredoxin reductase from Escherichia coli results in C135S with Cys138 remaining or C138S with Cys135 remaining. The expression system for the genes encoding thioredoxin reductase, wild-type enzyme, C135S, and C138S has been re-engineered to allow for greater yields of protein. Wild-type enzyme and C135S were found to be as previously reported, whereas discrepancies were detected in the characteristics of C138S. It was shown that the original C138S was a heterogeneous mixture containing C138S and wild-type enzyme and that enzyme obtained from the new expression system is the correct species. C138S obtained from the new expression system having 0.1% activity and 7% flavin fluorescence of wild-type enzyme was used in this study. Reductive titrations show that, as expected, only 1 mol of sodium dithionite/mol of FAD is required to reduce C138S. The remaining thiol in C135S and C138S has been reacted with 5,5'-dithiobis-(2-nitrobenzoic acid) to form mixed disulfides. The half time of the reaction was <5 s for Cys138 in C135S and approximately 300 s for Cys135 in C138S showing that Cys138 is much more reactive. The resulting mixed disulfides have been reacted with Cys32 in C35S mutant thioredoxin to form stable, covalent adducts C138S-C35S and C135S-C35S. The half times show that Cys138 is approximately fourfold more susceptible to attack by the nucleophile. These results suggest that Cys138 may be the thiol initiating dithiol-disulfide interchange between thioredoxin reductase and thioredoxin.     

Cysteine 351 is an essential nucleophile in catalysis by Porphyromonas gingivalis peptidylarginine deiminase

Peptidylarginine deiminase (PAD), which catalyzes the deimination of the guanidino group from peptidylarginine residues, belongs to a superfamily of guanidino group modifying enzymes that have been shown to produce an S-alkylthiouronium ion intermediate during catalysis. Thiol-directed reagents iodoacetamide and iodoacetate inactivate recombinant PAD, and substrate protects the enzyme from inactivation. Activity measurements together with peptide mapping by mass spectrometry of PAD modified in the absence and presence of substrate demonstrated that cysteine-351 is modified by iodoacetamide. The pK_a value of the cysteine residue, 7.7 ± 0.2 as determined by iodoacetamide modification, agrees well with a critical pK value identified in pH rate studies. The role of cysteine-351 in catalysis was tested by site-directed mutagenesis in which the cysteine was replaced with serine to eliminate the proposed nucleophilic interaction. Binding studies carried out using fluorescence spectrometry established the structural integrity of the C351S PAD. However, the C351S PAD variant was catalytically inactive, exhibiting <0.01% wild-type activity. These results indicate that Cys 351 is a nucleophile that initiates the enzymatic reaction.     

Solution structure and backbone dynamics of the reduced form and an oxidized form of E. coli methionine sulfoxide reductase A (MsrA): structural insight of the MsrA catalytic cycle

Methionine sulfoxide reductases (Msr) reduce methionine sulfoxide (MetSO)-containing proteins, back to methionine (Met). MsrAs are stereospecific for the S epimer whereas MsrBs reduce the R epimer of MetSO. Although structurally unrelated, the Msrs characterized so far display a similar catalytic mechanism with formation of a sulfenic intermediate on the catalytic cysteine and a concomitant release of Met, followed by formation of at least one intramolecular disulfide bond (between the catalytic and a recycling cysteine), which is then reduced by thioredoxin. In the case of the MsrA from Escherichia coli, two disulfide bonds are formed, i.e. first between the catalytic Cys51 and the recycling Cys198 and then between Cys198 and the second recycling Cys206. Three crystal structures including E. coli and Mycobacterium tuberculosis MsrAs, which, for the latter, possesses only the unique recycling Cys198, have been solved so far. In these structures, the distances between the cysteine residues involved in the catalytic mechanism are too large to allow formation of the intramolecular disulfide bonds. Here structural and dynamical NMR studies of the reduced wild-type and the oxidized (Cys51-Cys198) forms of C86S/C206S MsrA from E. coli have been carried out. The mapping of MetSO substrate-bound C51A MsrA has also been performed. The data support (1) a conformational switch occurring subsequently to sulfenic acid formation and/or Met release that would be a prerequisite to form the Cys51-Cys198 bond and, (2) a high mobility of the C-terminal part of the Cys51-Cys198 oxidized form that would favor formation of the second Cys198-Cys206 disulfide bond.     

Mutational analysis of cysteine 328 and cysteine 368 at the interface of Plasmodium falciparum adenylosuccinate synthetase

Plasmodium falciparum adenylosuccinate synthetase, a homodimeric enzyme, contains 10 cysteine residues per subunit. Among these, Cys250, Cys328 and Cys368 lie at the dimer interface and are not conserved across organisms. PfAdSS has a positively charged interface with the crystal structure showing additional electron density around Cys328 and Cys368. Biochemical characterization of site directed mutants followed by equilibrium unfolding studies permits elucidation of the role of interface cysteines and positively charged interface in dimer stability. Mutation of interface cysteines, Cys328 and Cys368 to serine, perturbed the monomer-dimer equilibrium in the protein with a small population of monomer being evident in the double mutant. Introduction of negative charge in the form of C328D mutation resulted in stabilization of protein dimer as evident by size exclusion chromatography at high ionic strength buffer and equilibrium unfolding in the presence of urea. These observations suggest that cysteines at the dimer interface of PfAdSS may indeed be charged and exist as thiolate anion.     

Structural determinants of substrate access to the disulfide oxidase Erv2p

Erv2p is a small, dimeric FAD-dependent sulfhydryl oxidase that generates disulfide bonds in the lumen of the endoplasmic reticulum. Mutagenic and structural studies suggest that Erv2p uses an internal thiol-transfer relay between the FAD-proximal active site cysteine pair (Cys121-Cys124) and a second cysteine pair (Cys176-Cys178) located in a flexible, substrate-accessible C-terminal tail of the adjacent dimer subunit. Here, we demonstrate that Cys176 and Cys178 are the only amino acids in the tail region required for disulfide transfer and that their relative positioning within the tail peptide is important for activity. However, intragenic suppressor mutations could be isolated that bypass the requirement for Cys176 and Cys178. These mutants were found to disrupt Erv2p dimerization and to increase the activity of Erv2p for thiol substrates such as glutathione. We propose that the two Erv2p subunits act together to direct the disulfide transfer to specific substrates. One subunit provides the catalytic domain composed of the active site cysteine residues and the FAD cofactor, while the second subunit appears to have two functions: it facilitates disulfide transfer to substrates via the tail cysteine residues, while simultaneously shielding the active site cysteine residues from non-specific reactions.