Shengwei Yu

An Oxyferrous Heme/Protein-based Radical Intermediate Is Catalytically Competent in the Catalase Reaction of Mycobacterium tuberculosis Catalase-Peroxidase (KatG)

A mechanism accounting for the robust catalase activity in catalase-peroxidases (KatG) presents a new challenge in heme protein enzymology. In Mycobacterium tuberculosis, KatG is the sole catalase and is also responsible for peroxidative activation of isoniazid, an anti-tuberculosis pro-drug. Here, optical stopped-flow spectrophotometry, rapid freeze-quench EPR spectroscopy both at the X-band and at the D-band, and mutagenesis are used to identify catalase reaction intermediates in M. tuberculosis KatG. In the presence of millimolar H2O2 at neutral pH, oxyferrous heme is formed within milliseconds from ferric (resting) KatG, whereas at pH 8.5, low spin ferric heme is formed. Using rapid freeze-quench EPR at X-band under both of these conditions, a narrow doublet radical signal with an 11 G principal hyperfine splitting was detected within the first milliseconds of turnover. The radical and the unique heme intermediates persist in wild-type KatG only during the time course of turnover of excess H2O2 (1000-fold or more). Mutation of Met255, Tyr229, or Trp107, which have covalently linked side chains in a unique distal side adduct (MYW) in wild-type KatG, abolishes this radical and the catalase activity. The D-band EPR spectrum of the radical exhibits a rhombic g tensor with dual gx values (2.00550 and 2.00606) and unique gy (2.00344) and gz values (2.00186) similar to but not typical of native tyrosyl radicals. Density functional theory calculations based on a model of an MYW adduct radical built from x-ray coordinates predict experimentally observed hyperfine interactions and a shift in g values away from the native tyrosyl radical. A catalytic role for an MYW adduct radical in the catalase mechanism of KatG is proposed.

Rapid formation of compound II and a tyrosyl radical in the Y229F mutant of Mycobacterium tuberculosis catalase-peroxidase disrupts catalase but not peroxidase function.

Catalase-peroxidases (KatG), which belong to Class I heme peroxidase enzymes, have high catalase activity and substantial peroxidase activity. The Y229F mutant of Mycobacterium tuberculosis KatG was prepared and characterized to investigate the functional role of this conserved residue unique to KatG enzymes. Purified, overexpressed KatG[Y229F] exhibited severely reduced steady-state catalase activity while the peroxidase activity was enhanced. Optical stopped-flow experiments showed rapid formation of Compound (Cmpd) II (oxyferryl heme intermediate) in the reaction of resting KatG[Y229F] with peroxyacetic acid or chloroperoxybenzoic acid, without detectable accumulation of Cmpd I (oxyferryl heme π-cation radical intermediate), the latter being readily observed in the wild-type enzyme under similar conditions. Facile formation of Cmpd III (oxyferrous enzyme) also occurred in the mutant in the presence of micromolar hydrogen peroxide. Thus, the lost catalase function may be explained in part because of formation of intermediates that do not participate in catalatic turnover. The source of the reducing equivalent required for generation of Cmpd II from Cmpd I was shown by rapid freeze-quench electron paramagnetic resonance spectroscopy to be a tyrosine residue, just as in wild-type KatG. The kinetic coupling of radical generation and Cmpd II formation was shown in KatG[Y229F]. Residue Y229, which is a component of a newly defined three amino acid adduct in catalase-peroxidases, is critically important for protecting the catalase activity of KatG.

Evidence for Radical Formation at Tyr-353 in Mycobacterium tuberculosis Catalase-Peroxidase (KatG)

Mycobacterium tuberculosis KatG is a heme-containing catalase-peroxidase responsible for activation, through its peroxidase cycle, of the front line antituberculosis antibiotic isoniazid (isonicotinic acid hydrazide). Formation of Compound I (oxyferryl heme-porphyrin π-cation radical), the classical peroxidase intermediate generated when the resting enzyme turns over with alkyl peroxides, is rapidly followed by production of a protein-centered tyrosyl radical in this enzyme. In our efforts to identify the residue at which this radical is formed, nitric oxide was used as a radical scavenging reagent. Quenching of the tyrosyl radical generated in the presence of NO was shown using electron paramagnetic resonance spectroscopy, and formation of nitrotyrosine was confirmed by proteolytic digestion followed by high performance liquid chromatography analysis of the NO-treated enzyme. These results are consistent with formation of nitrosyltyrosine by addition of NO to tyrosyl radical and oxidation of this intermediate to nitrotyrosine. Two predominant nitrotyrosine-containing peptides were identified that were purified and sequenced by Edman degradation. Both peptides were derived from the same M. tuberculosis KatG sequence spanning residues 346–356 with the amino acid sequence SPAGAWQYTAK, and both peptides contained nitrotyrosine at residue 353. Some modification of Trp-351 most probably into nitrosotryptophan was also found in one of the two peptides. Control experiments using denatured KatG or carried out in the absence of peroxide did not produce nitrotyrosine. In the mutant enzyme KatG(Y353F), which was constructed using site-directed mutagenesis, a tyrosyl radical was also formed upon turnover with peroxide but in poor yield compared with wild-type KatG. Residue Tyr-353 is unique to M. tuberculosis KatG and may play a special role in the function of this enzyme.

Characterization of the W321F mutant of Mycobacterium tuberculosis catalase–peroxidase KatG

A single amino acid mutation (W321F) in Mycobacterium tuberculosis catalase–peroxidase (KatG) was constructed by site‐directed mutagenesis. The purified mutant enzyme was characterized using optical and electron paramagnetic resonance spectroscopy, and optical stopped‐flow spectrophotometry. Reaction of KatG(W321F) with 3‐chloroperoxybenzoic acid, peroxyacetic acid, or t‐butylhydroperoxide showed formation of an unstable intermediate assigned as Compound I (oxyferryl iron:porphyrin π‐cation radical) by similarity to wild‐type KatG, although second‐order rate constants were significantly lower in the mutant for each peroxide tested. No evidence for Compound II was detected during the spontaneous or substrate‐accelerated decay of Compound I. The binding of isoniazid, a first‐line anti‐tuberculosis pro‐drug activated by catalase–peroxidase, was noncooperative and threefold weaker in KatG(W321F) compared with wild‐type enzyme. An EPR signal assigned to a protein‐based radical tentatively assigned as tyrosyl radical in wild‐type KatG, was also observed in the mutant upon reaction of the resting enzyme with alkyl peroxide. These results show that mutation of residue W321 in KatG does not lead to a major alteration in the identity of intermediates formed in the catalytic cycle of the enzyme in the time regimes examined here, and show that this residue is not the site of stabilization of a radical as might be expected based on homology to yeast cytochrome c peroxidase. Furthermore, W321 is indicated to be important in KatG for substrate binding and subunit interactions within the dimer, providing insights into the origin of isoniazid resistance in clinically isolated KatG mutants.

Radical Sites in Mycobacterium tuberculosis KatG Identified Using Electron Paramagnetic Resonance Spectroscopy, the Three-dimensional Crystal Structure, and Electron Transfer Couplings

Catalase-peroxidase (KatG) from Mycobacterium tuberculosis, a Class I peroxidase, exhibits high catalase activity and peroxidase activity with various substrates and is responsible for activation of the commonly used antitubercular drug, isoniazid (INH). KatG readily forms amino acid-based radicals during turnover with alkyl peroxides, and this work focuses on extending the identification and characterization of radicals forming on the millisecond to second time scale. Rapid freeze-quench electron paramagnetic resonance spectroscopy (RFQ-EPR) reveals a change in the structure of the initially formed radical in the presence of INH. Heme pocket binding of the drug and knowledge that KatG[Y229F] lacks this signal provides evidence for radical formation on residue Tyr229. High field RFQ-EPR spectroscopy confirmed a tryptophanyl radical signal, and new analyses of X-band RFQ-EPR spectra also established its presence. High field EPR spectroscopy also confirmed that the majority radical species is a tyrosyl radical. Site-directed mutagenesis, along with simulations of EPR spectra based on x-ray structural data for particular tyrosine and tryptophan residues, enabled assignments based on predicted hyperfine coupling parameters. KatG mutants W107F, Y229F, and the double mutant W107F/Y229F showed alteration in type and yield of radical species. Results are consistent with formation of a tyrosyl radical reasonably assigned to residue Tyr229 within the first few milliseconds of turnover. This is followed by a mixture of tyrosyl and tryptophanyl radical species and finally to only a tyrosyl radical on residue Tyr353, which lies more distant from the heme. The radical processing of enzyme lacking the Trp107-Tyr229-Met255 adduct (found as a unique structural feature of catalase-peroxidases) is suggested to be a reasonable assignment of the phenomena.

Role of the Oxyferrous Heme Intermediate and Distal Side Adduct Radical in the Catalase Activity of Mycobacterium tuberculosis KatG Revealed by the W107F Mutant

Catalase-peroxidase (KatG) is essential in Mycobacterium tuberculosis for oxidative stress management and activation of the antitubercular pro-drug isoniazid. The role of a unique distal side adduct found in KatG enzymes, involving linked side chains of residues Met255, Tyr229, and Trp107 (MYW), in the unusual catalase activity of KatG is addressed here and in our companion paper (Suarez, J., Ranguelova, K., Jarzecki, A. A., Manzerova, J., Krymov, V., Zhao, X., Yu, S., Metlitsky, L., Gerfen, G. J., and Magliozzo, R. S. (2009) J. Biol. Chem. 284, in press). The KatG[W107F] mutant exhibited severely reduced catalase activity yet normal peroxidase activity, and as isolated contains more abundant 6-coordinate heme in high spin and low spin forms compared with the wild-type enzyme. Most interestingly, oxyferrous heme is also found in the purified enzyme. Oxyferrous KatG[W107F] was prepared by photolysis in air of the carbonyl enzyme or was generated using hydrogen peroxide decayed with a t½ of 2 days compared with 6 min for wild-type protein. The stability of oxyenyzme was modestly enhanced in KatG[Y229F] but was not affected in KatG[M255A]. Optical stopped-flow experiments showed rapid formation of Compound I in KatG[W107F] and facile formation of oxyferrous heme in the presence of micromolar hydrogen peroxide. An analysis of the relationships between catalase activity, stability of oxyferrous enzyme, and a proposed MYW adduct radical is presented. The loss of catalase function is assigned to the loss of the MYW adduct radical and structural changes that lead to greatly enhanced stability of oxyenzyme, an intermediate of the catalase cycle of native enzyme.

Impact of Distal Side Water and Residue 315 on Ligand Binding to Ferric Mycobacterium tuberculosis Catalase-Peroxidase (KatG) †

The catalase-peroxidase (KatG) of Mycobacterium tuberculosis (Mtb) is important for the virulence of this pathogen and also is responsible for activation of isoniazid (INH), an antibiotic in use for over 50 years in the first line treatment against tuberculosis infection. Overexpressed Mtb KatG contains a heterogeneous population of heme species that present distinct spectroscopic properties and, as described here, functional properties. A six-coordinate (6-c) heme species that accumulates in the resting enzyme after purification is defined as a unique structure containing weakly associated water on the heme distal side. We present the unexpected finding that this form of the enzyme, generally present as a minority species along with five-coordinate (5-c) enzyme, is the favored reactant for ligand binding. The use of resting enzyme samples with different proportional composition of 5-c and 6-c forms, as well as the use of KatG mutants with replacements at residue 315 that have different tendencies to stabilize the 6-c form, allowed demonstration of more rapid cyanide binding and preferred peroxide binding to enzyme containing 6-c heme. Optical-stopped flow and equilibrium titrations of ferric KatG with potassium cyanide reveal complex behavior that depends in part on the amount of 6-c heme in the resting enzymes. Resonance Raman and low-temperature EPR spectroscopy clearly demonstrate favored ligand (cyanide or peroxide) binding to 6-c heme. The 5-c and 6-c enzyme forms are not in equilibrium on the time scale of the experiments. The results provide evidence for the likely participation of specific water molecule(s) in the first phases of the reaction mechanism of catalase-peroxidase enzymes.