Your search keyword '"Un S"' showing total 6 results

1. An evolutionary path to altered cofactor specificity in a metalloenzyme.

Author

Barwinska-Sendra A, Garcia YM, Sendra KM, Baslé A, Mackenzie ES, Tarrant E, Card P, Tabares LC, Bicep C, Un S, Kehl-Fie TE, and Waldron KJ

Subjects

Amino Acid Sequence, Bacterial Proteins chemistry, Bacterial Proteins genetics, Catalytic Domain, Evolution, Molecular, Iron chemistry, Isoenzymes classification, Isoenzymes genetics, Isoenzymes metabolism, Manganese chemistry, Metalloproteins chemistry, Metalloproteins genetics, Mutation, Oxidation-Reduction, Phylogeny, Sequence Homology, Amino Acid, Staphylococcus aureus genetics, Superoxide Dismutase chemistry, Superoxide Dismutase genetics, Superoxides metabolism, Bacterial Proteins metabolism, Iron metabolism, Manganese metabolism, Metalloproteins metabolism, Staphylococcus aureus enzymology, Superoxide Dismutase metabolism

Abstract

Almost half of all enzymes utilize a metal cofactor. However, the features that dictate the metal utilized by metalloenzymes are poorly understood, limiting our ability to manipulate these enzymes for industrial and health-associated applications. The ubiquitous iron/manganese superoxide dismutase (SOD) family exemplifies this deficit, as the specific metal used by any family member cannot be predicted. Biochemical, structural and paramagnetic analysis of two evolutionarily related SODs with different metal specificity produced by the pathogenic bacterium Staphylococcus aureus identifies two positions that control metal specificity. These residues make no direct contacts with the metal-coordinating ligands but control the metal's redox properties, demonstrating that subtle architectural changes can dramatically alter metal utilization. Introducing these mutations into S. aureus alters the ability of the bacterium to resist superoxide stress when metal starved by the host, revealing that small changes in metal-dependent activity can drive the evolution of metalloenzymes with new cofactor specificity.

Published

2020

2. A charge polarization model for the metal-specific activity of superoxide dismutases.

Author

Barwinska-Sendra A, Baslé A, Waldron KJ, and Un S

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Binding Sites, Catalytic Domain, Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Escherichia coli metabolism, Mutagenesis, Site-Directed, Nuclear Magnetic Resonance, Biomolecular, Oxidation-Reduction, Quantum Theory, Recombinant Proteins biosynthesis, Recombinant Proteins chemistry, Recombinant Proteins genetics, Superoxide Dismutase chemistry, Superoxide Dismutase genetics, Bacterial Proteins metabolism, Manganese chemistry, Staphylococcus aureus enzymology, Superoxide Dismutase metabolism

Abstract

The pathogenicity of Staphylococcus aureus is enhanced by having two superoxide dismutases (SODs): a Mn-specific SOD and another that can use either Mn or Fe. Using 94 GHz electron-nuclear double resonance (ENDOR) and electron double resonance detected (ELDOR)-NMR we show that, despite their different metal-specificities, their structural and electronic similarities extend down to their active-site 1 H- and 14 N-Mn(ii) hyperfine interactions. However these interactions, and hence the positions of these nuclei, are different in the inactive Mn-reconstituted Escherichia coli Fe-specific SOD. Density functional theory modelling attributes this to a different angular position of the E. coli H171 ligand. This likely disrupts the Mn-H171-E170' triad causing a shift in charge and in metal redox potential, leading to the loss of activity. This is supported by the correlated differences in the Mn(ii) zero-field interactions of the three SOD types and suggests that the triad is important for determining metal specific activity.

Published

2018

3. Activation of a unique flavin-dependent tRNA-methylating agent.

Author

Hamdane D, Bruch E, Un S, Field M, and Fontecave M

Subjects

Electron Spin Resonance Spectroscopy, Enzyme Stability, Free Radicals chemistry, Hydrogen-Ion Concentration, Methylation, Models, Chemical, Protein Binding, Protein Denaturation, Quantum Theory, RNA, Transfer chemistry, Bacillus subtilis enzymology, Bacterial Proteins chemistry, Flavin-Adenine Dinucleotide chemistry, tRNA Methyltransferases chemistry

Abstract

TrmFO is a tRNA methyltransferase that uses methylenetetrahydrofolate (CH2THF) and flavin adenine dinucleotide hydroquinone as cofactors. We have recently shown that TrmFO from Bacillus subtilis stabilizes a TrmFO-CH2-FADH adduct and an ill-defined neutral flavin radical. The adduct contains a unique N-CH2-S moiety, with a methylene group bridging N5 of the isoalloxazine ring and the sulfur of an active-site cysteine (Cys53). In the absence of tRNA substrate, this species is remarkably stable but becomes catalytically competent for tRNA methylation following tRNA addition using the methylene group as the source of methyl. Here, we demonstrate that this dormant methylating agent can be activated at low pH, and we propose that this process is triggered upon tRNA addition. The reaction proceeds via protonation of Cys53, cleavage of the C-S bond, and generation of a highly reactive [FADH(N5)═CH2]+ iminium intermediate, which is proposed to be the actual tRNA-methylating agent. This mechanism is fully supported by DFT calculations. The radical present in TrmFO is characterized here by optical and EPR/ENDOR spectroscopy approaches together with DFT calculations and is shown to be the one-electron oxidized product of the TrmFO-CH2-FADH adduct. It is also relatively stable, and its decomposition is facilitated by high pH. These results provide new insights into the structure and reactivity of the unique flavin-dependent methylating agent used by this class of enzymes.

Published

2013

4. Identification of Trp106 as the tryptophanyl radical intermediate in Synechocystis PCC6803 catalase-peroxidase by multifrequency Electron Paramagnetic Resonance spectroscopy.

Author

Jakopitsch C, Obinger C, Un S, and Ivancich A

Subjects

Bacterial Proteins chemistry, Electron Spin Resonance Spectroscopy, Hydrogen Bonding, Isotope Labeling, Kinetics, Models, Molecular, Peroxidases chemistry, Bacterial Proteins metabolism, Peroxidases metabolism, Synechocystis enzymology, Tryptophan chemistry

Abstract

The reactive intermediates formed in the catalase-peroxidase from Synechocystis PCC6803 upon reaction with peroxyacetic acid, and in the absence of peroxidase substrates, are the oxoferryl-porphyrin radical and two subsequent protein-based radicals that we have previously assigned to a tyrosyl (Tyr()) and tryptophanyl (Trp()) radicals by using multifrequency Electron Paramagnetic Resonance (EPR) spectroscopy combined with deuterium labeling and site-directed mutagenesis. In this work, we have further investigated the Trp() in order to identify the site for the tryptophanyl radical formation, among the 26 Trp residues of the enzyme and to possibly understand the protein constraints that determine the selective formation of this radical. Based on our previous findings about the absence of the Trp() intermediate in four of the Synechocystis catalase-peroxidase variants on the heme distal side (W122F, W106A, H123Q, and R119A) we constructed new variants on Trp122 and Trp106 positions. Trp122 is very close to the iron on the heme distal side while Trp106 belongs to a short stretch (11 amino acid residues on the enzyme surface) that is highly conserved in catalase-peroxidases. We have used EPR spectroscopy to characterize the changes on the heme microenvironment induced by these mutations as well as the chemical nature of the radicals formed in each variant. Our findings identify Trp106 as the tryptophanyl radical site in Synechocystis catalase-peroxidase. The W122H and W106Y variants were specially designed to mimic the hydrogen-bond interactions of the naturally occurring Trp residues. These variants clearly demonstrated the important role of the extensive hydrogen-bonding network of the heme distal side, in the formation of the tryptophanyl radical. Moreover, the fact that W106Y is the only Synechocystis catalase-peroxidase variant of the distal heme side that recovers a catalase activity comparable to the WT enzyme, strongly indicates that the integrity of the extensive hydrogen-bonding network is also essential for the catalatic activity of the enzyme.

Published

2006

5. Herbicide-induced changes in charge recombination and redox potential of Q(A) in the T4 mutant of Blastochloris viridis.

Author

Fufezan C, Drepper F, Juhnke HD, Lancaster CR, Un S, Rutherford AW, and Krieger-Liszkay A

Subjects

Bacterial Proteins genetics, Diuron pharmacology, Drug Resistance, Bacterial genetics, Electrochemistry, Hyphomicrobiaceae genetics, Kinetics, Mutation, Nitriles pharmacology, Oxidation-Reduction, Photosystem II Protein Complex genetics, Potentiometry, Spectrophotometry, Temperature, Triazines pharmacology, Bacterial Proteins chemistry, Bacterial Proteins drug effects, Herbicides pharmacology, Hyphomicrobiaceae chemistry, Hyphomicrobiaceae drug effects, Photosystem II Protein Complex chemistry, Photosystem II Protein Complex drug effects

Abstract

To gain new insights into the function of photosystem II (PSII) herbicides DCMU (a urea herbicide) and bromoxynil (a phenolic herbicide), we have studied their effects in a better understood system, the bacterial photosynthetic reaction center of the terbutryn-resistant mutant T4 of Blastochloris (Bl.) viridis. This mutant is uniquely sensitive to these herbicides. We have used redox potentiometry and time-resolved absorption spectroscopy in the nanosecond and microsecond time scale. At room temperature the P(+)(*)Q(A)(-)(*) charge recombination in the presence of bromoxynil was faster than in the presence of DCMU. Two phases of P(+)(*)Q(A)(-)(*) recombination were observed. In accordance with the literature, the two phases were attributed to two different populations of reaction centers. Although the herbicides did induce small differences in the activation barriers of the charge recombination reactions, these did not explain the large herbicide-induced differences in the kinetics at ambient temperature. Instead, these were attributed to a change in the relative amplitude of the phases, with the fast:slow ratio being approximately 3:1 with bromoxynil and approximately 1:2 with DCMU at 300 K. Redox titrations of Q(A) were performed with and without herbicides at pH 6.5. The E(m) was shifted by approximately -75 mV by bromoxynil and by approximately +55 mV by DCMU. As the titrations were done over a time range that is assumed to be much longer than that for the transition between the two different populations, the potentials measured are considered to be a weighted average of two potentials for Q(A). The influence of the herbicides can thus be considered to be on the equilibrium of the two reaction center forms. This may also be the case in photosystem II.

Published

2005

6. Protein-based radicals in the catalase-peroxidase of synechocystis PCC6803: a multifrequency EPR investigation of wild-type and variants on the environment of the heme active site.

Author

Ivancich A, Jakopitsch C, Auer M, Un S, and Obinger C

Subjects

Anisotropy, Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites, Cold Temperature, Electron Spin Resonance Spectroscopy, Free Radicals chemistry, Free Radicals metabolism, Heme metabolism, Models, Molecular, Mutagenesis, Site-Directed, Peroxidases genetics, Peroxidases metabolism, Protein Conformation, Tryptophan chemistry, Bacterial Proteins chemistry, Cyanobacteria enzymology, Heme chemistry, Peroxidases chemistry

Abstract

Catalase-peroxidases are bifunctional heme enzymes with a high structural homology to peroxidases from prokaryotic origin and a catalatic activity comparable to monofunctional catalases. These unique features of catalase-peroxidases make them good systems to study and understand the role of alternative electron pathways both in catalases and peroxidases. In particular, it is of interest to study the poorly understood role of tyrosyl and tryptophanyl radicals as alternative cofactors in the catalytic cycle of catalases and peroxidases. In this work, we have used a powerful combination of multifrequency EPR spectroscopy, isotopic labeling of tryptophan and tyrosine residues, and site-directed mutagenesis to unequivocally identify the reactive intermediates formed by the wild-type Synechocystis PCC6803 catalase-peroxidase. Selected variants of the heme distal and proximal sides of the Synechocystis enzyme were investigated. Variants on the aromatic residues of the short stretch located relatively close to the heme and spanning the distal and proximal sides were also investigated. In the wild-type enzyme, the EPR signal of the catalases and peroxidases (typical) Compound I intermediate [Fe(IV)=O por.+] was observed. Two protein-based radical intermediates were also detected and identified as a Tyr. and a Trp. . The site of Trp. is proposed to be Trp 106, a residue belonging to the conserved short stretch in catalase-peroxidases and located at a 7-8 A distance to the heme propionate groups. An extensive hydrogen-bonding network on the heme distal side, involving Trp122, His123, Arg119, seven structural waters, the heme 6-propionate group, and Trp106, is proposed to have a key role on the formation of the tryptophanyl radical. We used high-field EPR spectroscopy (95-285 GHz) to resolve the g-anisotropy of the protein-based radicals in Synechocystis catalase-peroxidase. The broad gx component of the HF EPR spectrum of the Tyr. in Synechocystis catalase-peroxidase was consistent with a distributed electropositive protein environment to the tyrosyl radical.

Published

2003